JP3851236B2 - Strobe light emission control device - Google Patents

Description

[0001]
【Technical field】
The present invention relates to a strobe light emission control device.
[0002]
BACKGROUND OF THE INVENTION
The automatic light control strobe emits strobe light to the subject, receives the reflected light, and stops the strobe emission when the amount of light received reaches a predetermined brightness. As described above, the automatic light control strobe controls the total amount of light applied to the subject by adjusting the irradiation time of the strobe light. When the subject is at a short distance, it is necessary to perform light emission control relatively accurately so that the total amount of light applied to the subject is reduced. However, since it is relatively difficult to accurately control the light emission of the strobe light emitting device, it is often difficult to accurately control the total amount of light applied to the subject.
[0003]
DISCLOSURE OF THE INVENTION
An object of the present invention is to control the total amount of light irradiated to a subject relatively accurately.
[0004]
A strobe light emission control device according to the present invention is a light receiving element that outputs a light reception signal corresponding to the amount of incident light received, a strobe light that irradiates the subject with strobe light, and stops light emission in response to a given strobe light emission stop signal. A first strobe light emission control circuit for controlling the light emitting device, an integration circuit that is reset when the strobe light emitting device starts to emit light, is reset in response to a given reset signal, and integrates the received light signal output from the light receiving element; The integration value of the integration circuit is compared with the first reference value, and when the integration value is equal to or greater than the first reference value, the detection circuit outputs a detection signal and the comparison circuit outputs the detection signal. A reset signal is output to the integration circuit in response to the detection signal being output before the first predetermined time has elapsed from the start of light emission of the strobe light emitting device. A first control circuit is provided that outputs a strobe light emission stop signal to the first strobe light emission control circuit in response to the output after a first predetermined time has elapsed since the start of light emission of the strobe light emitting device. To do.
[0005]
You may make it provide the control method of the flash light emission control apparatus by this invention. That is, in this method, a light receiving element that outputs a light receiving signal corresponding to the amount of incident light received, a strobe light emitting device that irradiates the subject with strobe light and stops light emission according to a given strobe light emission stop signal. A first strobe light emission control circuit to be controlled, and an integration circuit that is reset in response to the start of light emission of the strobe light emitting device and that is reset according to a given reset signal and integrates the light reception signal output from the light receiving element. In the strobe light emission control device, the integration value of the integration circuit is compared with the first reference value, and when the integration value is equal to or greater than the first reference value, a detection signal is output, and the detection signal is A reset signal is output to the integration circuit in response to the output before the first predetermined time has elapsed from the start of light emission of the light emitting device, and the strobe light emitting device From light emission start in response to output after elapse the first predetermined time and outputs a strobe light emission stop signal to the first strobe light emission control circuit.
[0006]
According to the present invention, the subject is irradiated with the strobe light from the strobe light emitting device. Reflected light of strobe light from the subject is received by the light receiving element, and a light reception signal is output. The strobe light emission control device is provided with an integration circuit that is reset at the start of light emission of the strobe light emission device. The received light signal is integrated by this integration circuit. The integration value of the integration circuit and the first reference value are compared in the comparison circuit, and a detection signal is output when the integration value is equal to or greater than the first reference value. When the detection signal is output before the first predetermined period has elapsed from the start of light emission of the strobe light emitting device, a reset signal is output to the integration circuit, and the integration circuit is reset. The integration operation in the integration circuit is performed from the beginning. When the detection signal is output after the first predetermined period has elapsed from the start of light emission of the strobe light emitting device, a strobe light emission stop signal is output to the strobe light emission control circuit, and the strobe light emission of the strobe light emitting device is stopped.
[0007]
The characteristic of the emitted light level of the strobe light emitting device rises sharply immediately after the start of light emission and then gradually decreases. Therefore, it is necessary to relatively accurately perform control such as strobe light emission stop immediately after the light emission starts. According to the present invention, when the detection signal is output within the first predetermined period from the start of the strobe light emission, the integration circuit is reset, and the received light signal obtained when the light emitted from the strobe light emitting device becomes smaller is obtained. The strobe light emission stop control is performed again based on the integrated value. Even if the strobe light emission stop control is not accurate, the total amount of light applied to the subject can be controlled relatively accurately. In such a strobe light emission control device, when strobe light emission stop control is performed again, the subject is imaged synchronously when the strobe light emission stop control is performed again, and the image data obtained by the imaging is recorded on the recording medium. Needless to say, it is recorded. If the strobe light emission stop control is not performed again, image data obtained by imaging the subject in synchronization with the start of light emission of the strobe light emitting device will be recorded on the recording medium.
[0008]
The strobe emission control device is applied to a solid-state electronic image pickup device that picks up an image of a subject and outputs a video signal representing the image of the subject, and an electronic still camera including a diaphragm disposed in front of a light receiving surface of the solid-state electronic image pickup device. It may be done. In this case, in response to the output of the reset signal from the first control circuit, the accumulated charge of the solid-state electronic image sensor will be reset. Further, the diaphragm is controlled so as to reduce the aperture, and the integrated value of the integrating circuit is compared with a second reference value that is larger than the first reference value, and the integrated value is the second reference value. A second control circuit for controlling the comparison circuit so as to output a detection signal when the value becomes equal to or greater than the value may be provided.
[0009]
Since the aperture opening is reduced, the amount of light per unit time incident on the light receiving surface of the solid-state electronic image sensor is reduced. Even when the strobe light emission stop control timing is not accurate, image data having a relatively appropriate exposure amount can be obtained.
[0010]
The second control circuit is responsive to the detection signal detected from the comparison circuit being output before a second predetermined time shorter than the first predetermined time from the start of light emission to the strobe light emitting device. The aperture control and the comparison circuit control may be performed.
[0011]
[Explanation of Examples]
FIG. 1 is a block diagram showing a part of the electrical configuration of a digital still camera according to an embodiment of the present invention.
[0012]
The entire operation of the digital still camera is controlled by the CPU 10.
[0013]
A strobe emission command given by the user (when a strobe emission mode or the like is set, a strobe emission command is generated by pressing the shutter release button) is input to the CPU 10. Then, the strobe emission command signal S1 is input to the control circuit 11. A strobe control signal S2 for controlling strobe emission is output from the control circuit 11 to the discharge tube 13. Strobe light is emitted from the discharge tube 13 and irradiated to the subject ob. The control circuit 11 includes a timer 12. The timer 12 starts timing as the discharge tube 13 starts to emit light.
[0014]
Reflected light from the subject ob enters the light receiving element 14. A light reception signal S3 corresponding to the amount of light received is output from the light receiving element. The received light signal S3 is input to the integrating circuit 15 and integrated. An integration signal S4 indicating the integration value of the integration circuit 15 is supplied to one input terminal of the comparison circuit 17. A threshold voltage output from the variable reference voltage source 16 is applied to the other input terminal of the comparison circuit 17. The variable reference voltage source 16 switches between the first threshold voltage Th1 and the second threshold voltage Th2 based on a switching control signal from the CPU 10. As described above, the first threshold voltage Th1 or the second threshold voltage Th2 is applied to the other input terminal of the comparison circuit 17.
[0015]
When the integral value signal S4 input to one input terminal of the comparison circuit 17 is equal to or higher than the threshold voltage supplied from the variable reference voltage source 16 to the other input terminal, the detection signal S5 is output from the comparison circuit 17. . The detection signal S5 is input to the strobe control circuit 11 and the CPU 10. Specifically, as described later, when the detection signal S5 is input to the control circuit 11 within a first predetermined time from the start of light emission of the discharge tube 13, a reset signal is output from the control circuit 11, and the integration circuit 15 and the drive circuit 9 To enter. Then, the integration circuit 15 is reset, and integration of the light reception signal S3 output from the light receiving element 14 is started again from the beginning. If the detection signal S5 is not input to the control circuit 11 within the first predetermined time from the start of light emission of the discharge tube 13, the detection signal S5 is input to the control circuit 11 after the first predetermined time elapses, whereby the control circuit 11 The discharge tube 13 is supplied with a strobe control signal S2 for controlling the strobe emission stop. Strobe light emission is stopped by the discharge tube 13.
[0016]
A diaphragm 1 and an imaging lens 2 are provided in front of a light receiving surface of a CCD (solid-state electronic imaging device). The aperture value of the aperture 1 is controlled by an aperture motor 8 controlled by the CPU 10. The light indicating the optical image of the subject ob passes through the aperture of the diaphragm 1 and passes through the imaging lens 2 and forms an image on the light receiving surface of the CCD 3. The CCD 3 is controlled based on a drive control signal from the drive circuit 9. A video signal representing the subject image is output from the CCD 3 and input to the analog / digital conversion circuit 4. An analog / digital conversion circuit 4 converts an analog video signal into digital image data. The converted digital image data is subjected to predetermined signal processing such as gamma correction and white balance adjustment in the signal processing circuit 5. The image data is given to the memory card 7 through the card interface and recorded.
[0017]
FIG. 2 shows the light emission amount-light emission time characteristic of the discharge tube 13.
[0018]
The amount of light emitted from the discharge tube 13 increases rapidly immediately after the start of light emission, and gradually decreases as time elapses. For example, the amount of light emission reaches a peak when 50 μs has elapsed from the start of light emission, and then gradually decreases.
[0019]
As described above, the light emitted from the discharge tube 13 emits a lot of light immediately after light emission, so that it is relatively accurate to adjust the amount of light irradiated to the subject by stopping the light emission immediately after light emission. It is required to control the stop of the light emitted from the discharge tube 13. In this embodiment, if the integration signal exceeds the threshold voltage output from the variable reference voltage source 16 as described above before the first predetermined time (50 μs) has elapsed from the start of light emission of the discharge tube 13, Since the object ob is near, it is determined that accurate exposure control cannot be performed. Then, the subject irradiated with the light emitted from the discharge tube 13 after the first predetermined time has elapsed from the start of light emission of the discharge tube 13 is imaged.
[0020]
FIG. 3 is a time chart showing signals flowing through each circuit of the digital still camera shown in FIG.
[0021]
When the shutter release button (not shown) is pressed while the digital still camera is set to the flash emission mode, a flash emission command is given to the CPU 10. Then, at time t11, the flash emission command signal S1 is given from the CPU 10 to the control circuit 11. When the strobe light emission command signal S1 is input to the control circuit 11, a strobe light emission control signal S2 is given from the control circuit 11 to the discharge tube 13. Light emission of the discharge tube 13 is started. In addition, when the strobe light emission control signal S2 is given from the control circuit 11 to the discharge tube 13, the timer 12 is reset at the same timing to start measuring time.
[0022]
The light emitted from the discharge tube 13 is applied to the subject ob. Reflected light from the subject ob is received by the light receiving element 14. The light receiving element 14 outputs a light receiving signal S3 corresponding to the amount of received light. The level-time characteristic of the light reception signal S3 has the same characteristic as the light emission amount-light emission time characteristic of the discharge tube 13 shown in FIG. 2, and immediately rises sharply immediately after the discharge tube 13 starts to emit light. The level gradually decreases as time passes.
[0023]
The light receiving signal S3 output from the light receiving element 14 is integrated in the integrating circuit 15. An integration signal S4 indicating the integration value of the integration circuit 15 is input to one input terminal of the comparison circuit 17. The first threshold voltage Th1 is first output from the variable reference voltage source 16. The first threshold voltage Th1 is input to the other input terminal of the comparison circuit 17. When the integration signal S4 exceeds the first threshold value Th1, a detection signal S5 is output from the comparison circuit 17 and input to the control circuit 11.
[0024]
If the time t12 when the detection signal S5 is input to the control circuit 11 is the time before the first predetermined time (50 μs) has elapsed (FIG. 3 shows the case where the time t12 is before the first predetermined time). As described above, the subject ob is considered to be near the digital still camera. Since the amount of reflected light from the subject ob per unit time is large, it is necessary to accurately control the light emission stop of the discharge tube 13. However, it is relatively difficult to accurately control the light emission stop of the discharge tube 13, so accurate exposure control cannot be performed. A reset signal S6 is given from the control circuit 11 to the integrating circuit 15.
[0025]
When the detection signal S5 is input to the control circuit 11 before the first predetermined time elapses, the opening adjustment signal S7 is given from the control circuit 11 to the CPU 10. Then, an aperture control signal S8 is given from the CPU 10 to the aperture motor 8. The aperture of the aperture 1 is reduced by the aperture motor 8. Further, the CPU 10 changes the threshold voltage output from the variable reference voltage source 16 from the first threshold voltage Th1 to the second threshold voltage Th2 which is larger than the first threshold voltage Th1. It is done.
[0026]
When the integration circuit 15 is completely reset at time t13, the integration of the light reception signal S3 is started again by the integration circuit 15.
[0027]
When the integration signal S4 output from the integration circuit 15 becomes greater than or equal to the second threshold value Th2 at time t14, the detection signal S5 is output again from the comparison circuit 17 and input to the control circuit 11. Since a detection signal is input to the control circuit 11 after the first predetermined time has elapsed from the start of light emission of the discharge tube 13, a strobe control signal indicating stop of light emission is given from the control circuit 11 to the discharge tube 13. The light emission of the discharge tube 13 is stopped.
[0028]
Image data representing an image photographed by the CCD 3 between times t13 and t14 is recorded on the memory card 7. From time t13 to t14, the light emission amount per unit time of the discharge tube 13 is relatively small. For this reason, the exposure control of the CCD 3 can be performed relatively accurately without performing the emission stop control accurately. In particular, the diaphragm 1 is controlled so that the aperture is small, and the threshold voltage applied to the comparison circuit 17 is also adjusted to be large. For this reason, the time until the detection signal S5 is output again from the comparison circuit 17 becomes longer. Exposure control can be realized relatively accurately.
[0029]
FIG. 4 shows another embodiment, and is a time chart showing signals flowing in each circuit of the digital still camera shown in FIG.
[0030]
In the above-described embodiment, when the detection signal S5 is output from the comparison circuit 17 within the first predetermined time, the threshold voltage applied to the comparison circuit 17 is changed from the first threshold voltage Th1 to the second threshold voltage. In this embodiment, the threshold voltage is fixed to a predetermined threshold voltage Th and the diaphragm 1 is also changed. I can't let you. The aperture 1 itself may not be provided.
[0031]
When a strobe emission command is given, a strobe emission command signal S1 is input from the CPU 10 to the control circuit 11 at time t21. A strobe control signal S2 is given from the control circuit 11 to the discharge tube 13, and light emission by the discharge tube 13 is started. The timer 12 starts timing. As described above, the light receiving signal S3 from the light receiving element 14 is input to the integrating circuit 15 and integrated. The integration signal S4 from the integration circuit 15 is supplied to the comparison circuit 17. When the integration signal S4 exceeds the fixed threshold voltage Th at time t22 within the first predetermined time, the detection signal S5 is output from the comparison circuit 17.
[0032]
The reset signal S6 is given from the control circuit 11 to the integrating circuit 15, and the integrating circuit 15 is reset. The integration of the integration circuit 15 is started again from time t23, and the integration signal S4 again exceeds the threshold voltage Th at time t24. Then, a strobe control signal S2 for stopping light emission is given from the control circuit 11 to the discharge tube 13. The light emission of the discharge tube 13 stops.
[0033]
In the embodiment described above, the integration circuit 15 is reset, the threshold voltage is changed, etc., depending on whether the detection signal is output from the comparison circuit 17 within the first predetermined time (50 μs) from the start of light emission. However, when a second predetermined time (for example, 30 μs) shorter than the first predetermined time is specified and the detection signal S5 is output from the comparison circuit 17 within the second predetermined time, as shown in FIG. The aperture of the diaphragm 1 may be reduced and the threshold voltage may be changed. In this case, when the detection signal S5 is output from the comparison circuit 17 within the first predetermined time after the lapse of the second predetermined time, as shown in FIG. The reset operation of the integration circuit 15 may be performed without changing.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an electrical configuration of a digital still camera.
FIG. 2 shows a light emission amount-light emission time characteristic of a discharge tube.
FIG. 3 is a time chart showing signals flowing through each circuit of the digital still camera.
FIG. 4 is a time chart showing signals flowing through each circuit of the digital still camera.
[Explanation of symbols]
1 Aperture 3 CCD
8 Aperture motor
10 CPU
11 Control circuit
12 timer
13 discharge tube
14 Photo detector
15 Integration circuit
16 Reference voltage source
17 Comparison circuit
ob Subject

Claims (4)

A light receiving element that outputs a light reception signal corresponding to the amount of incident light received;
A first strobe light emission control circuit for controlling the strobe light emission device to irradiate the subject with strobe light and to stop the light emission in response to a given strobe light emission stop signal;
An integration circuit that integrates a light reception signal that is reset upon the start of light emission of the strobe light emitting device and that is reset in response to a given reset signal and is output from the light receiving element;
The integration value of the integration circuit is compared with the first reference value, and when the integration value is equal to or greater than the first reference value, the detection circuit outputs a detection signal and the comparison circuit outputs the detection signal. A reset signal is output to the integration circuit in response to the detection signal being output before the first predetermined time has elapsed since the start of light emission of the strobe light emitting device, and after the first predetermined time has elapsed from the start of light emission of the strobe light emitting device. A first control circuit for outputting a strobe light emission stop signal to the first strobe light emission control circuit in response to the output;
Strobe light emission control device. The strobe emission control device is applied to a solid-state electronic image pickup device that picks up an image of a subject and outputs a video signal representing the image of the subject, and an electronic still camera including a diaphragm disposed in front of a light receiving surface of the solid-state electronic image pickup device. Is,
A reset circuit for resetting accumulated charges of the solid-state electronic imaging device in response to a reset signal output from the first control circuit;
The strobe light emission control device according to claim 1, further comprising: The strobe emission control device is applied to a solid-state electronic image pickup device that picks up an image of a subject and outputs a video signal representing the image of the subject, and an electronic still camera including a diaphragm disposed in front of a light receiving surface of the solid-state electronic image pickup device. Is,
In response to the output of the reset signal from the first control circuit, the charge stored in the solid-state electronic image pickup device is reset, the diaphragm is controlled to reduce the aperture, and the integration value of the integration circuit is A second reference value that is larger than the first reference value is compared, and when the integral value is greater than or equal to the second reference value, the comparison circuit is controlled to output a detection signal. 2 control circuits,
The strobe light emission control device according to claim 1, further comprising: The second control circuit is responsive to the detection signal detected from the comparison circuit being output before a second predetermined time shorter than the first predetermined time from the start of light emission to the strobe light emitting device. The strobe light emission control device according to claim 3, wherein the aperture control and the comparison circuit control are performed.

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