JPS58104573A - Electronic camera - Google Patents

Abstract

PURPOSE:To prevent useless flushing of a flush device after the end of charge storage, by synchronizing the start of charge storage of an image pickup element with the start of flushing of the flush device, and the start of transfer of the image pickup element with the stop of flushing respectively. CONSTITUTION:The start of flushing of a flush device 10 is done with a flush start signal from a control circuit 4 and the stop of flushing is done with a flush stop signal from an automatic light control circuit incorporated in the flush device. The flush device 10 generates the stop signal and transmits a signal in synchronizing with the signal to the control circuit 4. The control circuit 4 receives this signal and transmits a transfer pulse to a solid-state image pickup device 2 immediately to transfer the stored charge to a logitudinal shift register and completes the storage of charge.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention is an electronic camera that is equipped with a built-in flash device, is removable, and uses a solid-state image sensor (an electronic camera that converts a formed subject image into a still image signal and records it. →(related)

Conventionally, this type of electronic camera
The one described in Publication No. 4 is known. This electronic camera uses an incline transfer type C as a solid-state image sensor.
CD (hereinafter referred to as ILTCCD) is adopted, and the start of charge accumulation of the I-L T CCD, that is, the start of exposure, and the start of light emission of the flash device are synchronized with the generation of a shooting start signal, and the time point when a predetermined exposure amount is obtained. The charges accumulated in each light receiving element of the ILTCCD are transferred to the vertical shift register by opening the transfer gate. Then, the transferred charges are sequentially read out via a horizontal shift register to obtain an image signal for one frame. However, since no signal is sent to the flash device at this point, it continues to emit light that does not contribute to exposure, resulting in wasted power consumption.

An object of the present invention is to obtain an electronic camera that does not emit unnecessary flash light.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a pull diagram showing the circuit configuration of the electronic camera of the present invention. In the figure, a subject image is formed on an image sensor 2 by a photographing lens 1. Further, a part of the subject light that has passed through the lens 1 is sent to the photometric element 3. The photometric element 3 sends object brightness information to the control circuit 4. Image sensor 2
is driven by various control signals from the control circuit 4, and sends time-series signals corresponding to the subject image to the image signal processing circuit 5. The processing circuit 5 receives the synchronization signal from the control circuit II4, performs processing such as amplification and modulation on the image signal from the image sensor 2, and creates a video signal. The storage device M6 includes a storage medium such as a magnetic tape or a magnetic disk, and the processing circuit 5
A video signal from the computer is stored on a storage medium.

The switch 7 is closed in response to a half-press of the trigger button 8, and power supply to all circuits is started via the control circuit 4. The switch 9 is closed when the trigger button 8 is fully pressed, and the photographing operation is started via the control circuit 4.

The amount of light emitted by the flash device 10 is controlled by a light emission start signal and a stop signal from the control circuit 4.

FIG. 2 shows an example of a solid-state image sensor. This is IL
In TCCD, light receiving elements a1.1, al.2,...
・711・n, &2・1,・・・・−・,al・n
l..., ``m・1, 1mso2, ...
..., 1m'n are arranged in an mxn matrix to form a light receiving section. The total number of light-receiving elements, that is, the number of pixels, is preferably about 10'.

These rows of light-receiving elements, e.g. al.1, al.
Transfer gates TG1.1, . ．． and TG2. , is installed. When a transfer signal φTG is applied via the terminal 2c, the TG4,1 transfers charges corresponding to the amount of incident light accumulated in each element to the vertical CCD analog shift register Sv1.

On the other hand, the gate T02.1 receives the transfer signal φT via the terminal 2b.
When G2 is applied, the charge is transferred to the over 7 u-drain region OD1. Note that the electrical potential of transfer gate TG2.1 is equal to the transfer signal φT6.
2 is not applied, the potential is slightly lower than the potential between the light receiving elements and the potential between each bit of the vertical shift register Sv1. Therefore, the charges overflowing from the light-receiving element nohotential wells flow in the lower barrier direction, that is, over 7g-drain 0D1 (over 7g-drain 0D1), and the occurrence of the pluming phenomenon is prevented.The above is exactly the same for the other rows of light-receiving elements. From output terminal 2, over 7--drain OD1,
......, the charge transferred to ODn is output, and the input terminal 2bC is connected to the transfer gate TG2+1,...
..., TG2. . A transfer signal φT G2 is input to the transfer gate TG1, and the input terminal 2cr- is input to the transfer gate TG1.
．． 1, ......, TG1, transfer signal φTG1 to n
is input.

Transfer gate TG1.1,..., TG
The charges transferred to the vertical shift registers Sv1, . Transferred to the lower 10,000 vl, v
2 and sent to each bit of the horizontal shift register Sh. Then, it is transferred to the right by the lateral transfer pulses φ, 1, φh2C inputted via the input terminals 2f, 2g, amplified by the sense amplifier AC, and taken out from the terminal 2.

Next, the operation of this embodiment will be explained with reference to the timing chart shown in FIG. When the trigger button 8 is pressed halfway, the switch 7 is turned on as shown in FIG. 3(m), and a power supply start signal is sent to the control circuit 4. Control circuit 4
In response to this, power supply to all circuits is started as shown in FIG. 5, etc., and this is maintained until the photographing is completed. Accordingly, the transfer signal φTG2 at the H level shown in FIG. 3(C) is applied from the control circuit 4 to the input terminal 2b.

As a result, each transfer gate TG2,1, TG2.2, etc. located on the right side of each light receiving element row
・, TG2. fl enters the ON state. Therefore, the charges generated in each light receiving element are not accumulated and are transferred to the overflow drain OD, OD, ......, ODn.
and is discharged via the output terminal 2a. At this time, each light receiving element is in a reset state.

When the trigger button 8 is fully pressed, a photographing start signal shown in the 31st XJ (d) c is sent to the control circuit 4. Control circuit 4
As soon as it receives this signal, it stops applying the transfer signal φTG2 shown in FIG.
,2,...,TG2. . Turn off. At this time, TG1.1, TG 1.2,...-=, TG
,, n40 FF Since it is in the F state, charge accumulation in each light receiving element immediately starts as shown in FIG. A light emission start signal is sent as shown in (f).The flash device 11 thereby emits light toward the subject as shown in the third factor. Charges corresponding to the subject image illuminated by the flash unit 11 are accumulated in each light-receiving element. The control circuit 4 receives the object brightness information from the photometric element 5 and controls the third FI when an appropriate exposure amount is obtained.
IJ(hl) Sends a light emission stop signal to the flash unit 11 as shown.

As a result, the flash device 11 stops emitting light as shown in FIG. 5(g)C. In synchronization with this, the control circuit 4 sends a transfer signal φTG shown in FIG.
1, TG 1.2, ..., TGl, n are momentarily turned on, and the accumulated charges in each light receiving element row are vertically shifted and transferred to register sv1, river...' ”vn. Now, the charge accumulation of each light-receiving element is as shown in Figure 3 (
Finish as shown in e). Subsequently, the control circuit 4
As shown in the figure (cl), the transfer signal φTG2 is generated.
......, TG2. n becomes an ON-like layer, and each light-receiving element is in a reset state again.

Subsequently, the control circuit 4 generates a two-phase longitudinal transfer pulse φ94.
, φy2 (the 51st ffi (pulse φ7. shown in jl) is sent to the vertical shift registers Sv1, . , Self..., 5vnC The accumulated charges transferred are sequentially transferred downward and sent to each bit of the horizontal shift register Sh. The control circuit 4 generates two-phase horizontal transfer pulses synchronized with the vertical transfer pulses. φh1, φh2 (Figure 3(k) r-pulse φh
1) is sent to the horizontal shift register Sh via input terminals 2f and 2g. This causes the horizontal shift register Sh (the transferred accumulated charge is amplified by the sense amplifier A, then outputted from the output terminal 2h as an image signal, and sent to the image signal layer circuit 5. The processing circuit 5 The input image signals are sequentially processed and sent to the storage device.

When all the accumulated charges, that is, the image signals for one plane are recorded in the storage device 6 via the image signal processing circuit 5, the power supply is automatically cut off as shown in FIG. Shooting of the still image of the area is completed.

While FIG. 1 shows a so-called TTL true light type flash device and camera, FIG. 4 shows an external dimming type flash device and camera. Components that are the same as those in FIG. 1 are given the same reference numerals and explanations will be omitted, and only the differences will be explained. In FIG. 4, a flash device 10 has a built-in automatic light control circuit that receives subject brightness information from a photometric element 3 and issues a light emission stop signal when the amount of light emission reaches a predetermined value. flash! The light emission start of 110 is performed by the light emission start signal from the control circuit 4 as in the case of FIG. This is done by The flash 9910 sends a signal to the control circuit 4 simultaneously with the generation of this light emission stop signal. Immediately upon receiving this, the control circuit 4 sends a transfer pulse φTG to the ILTCCD 2, transfers the accumulated charge to the vertical shift register, and ends charge accumulation.

The following operations are similar to those in the embodiment shown in FIG.

Incidentally, the flash device 10 of the above embodiment may be configured to be detachable from the camera body.

Further, in this embodiment, an interline transfer type CCD is exemplified as the solid-state image sensor, but the present invention is not limited to this, and a frame transfer type CCD or another solid-state image sensor such as a BBD may be used.

According to the present invention, the start of charge accumulation in the image sensor, the start of light emission of the flash device, and the start of transfer of the accumulated charge of the image sensor and the stop of light emission of the flash device are performed in synchronization, so that the flash device completes charge accumulation. This prevents unnecessary light emission later.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of one embodiment of the present invention, FIG. 2 is a diagram showing a specific example of the solid-state image sensor used in the same embodiment, and FIG.
The figure is a timing chart showing the operation sequence of this embodiment. <Explanation of symbols of main parts> Solid-state image sensor...2 Flash device...
・・・・・・・・・・・・・・・・・・・・・1゜Control circuit・・・・・・・・・・・・・・・・・・・・・4 Applicant: Nippon Kogaku Kogyo Co., Ltd. - Agent Takashi Watanabe Male procedure amendment (Form) 4μ, 1980 Director General of the Patent Office Shima 1) Haruki Tono1, Indication of the case 1982 Patent Application No. 2039632, Invention Name Electronic Camera 3, Relationship with the person making the amendment Patent Applicant: 3-2-3 Marunouchi, Chiyoda-ku, Tokyo (411) Nippon Kogaku Kogyo Co., Ltd. 4, Agent: 1-6 Nishi-Oi, Honbunagawa-ku, Tokyo 140 No. 3 No. 5, date of amendment order: March 5, 1982 (Shipping date: March 3, 1982)
0th) 6. This is a timing chart showing [s] in the first line of page 12 of the specification in the "Brief Description of Drawings" section of the specification to be amended. 4 is a block diagram of another embodiment of the present invention."

Claims (1)

[Scope of Claims] (1) A flash device is built-in or removable, and includes a solid-state image sensor (starts charge accumulation in the image sensor, starts emitting light from the flash device, and An electronic camera characterized in that the transfer start of the flash unit and the stop of light emission of the flash unit are performed in synchronization with each other. and a control circuit for generating a light emission start signal and a light emission stop signal for causing the flash device to stop emitting light in synchronization with the start of transfer of the accumulated charge of the flash unit image sensor. Range 1
Electronic camera as described in section. (5) When a light emission start signal for causing the flash device to start emitting light is generated in synchronization with the start of charge accumulation in the solid-state image sensor, ``the flash device stops emitting light (receiving the light emission stop signal generated accordingly). 2. The electronic camera according to claim 1, further comprising a control circuit for starting transfer of the accumulated charge of the solid-state image sensor.