JP2000180950A - Photographing operation controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To respectively record a subject image having the same moving body distortion in silver salt film and a memory at the time of photographing a moving object. SOLUTION: The silver salt film is exposed by driving a focal plane shutter by a shutter driving circuit at a photographing time, and a picture signal generated at an MOS type imaging device is simultaneously read out per each line. Then, the moving direction of a slit formed at the time of actuating the focal plane shutter coincides with a scanning direction at the time of reading out the picture signal from the MOS type imaging device. Also, the moving speed of the slit coincides with scanning speed to read out the picture signal, and exposure time for the silver salt film coincides with that for the MOS type imaging device.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a camera capable of recording an image on a silver halide film and simultaneously storing the image recorded on the silver halide film in a memory as image data.

[0002]

2. Description of the Related Art Conventionally, this kind of camera is configured to form an image same as an image recorded on a silver halide film on an image pickup device and store an image signal generated by photoelectric conversion in a memory as image data. ing. When the shutter provided in the camera is a focal plane shutter and shooting is performed at a high shutter speed, a slit formed near the silver halide film moves in parallel from end to end of the film surface during exposure. Exposes the silver halide film. Further, when the camera is provided with a MOS type imaging device formed two-dimensionally by a photoelectric conversion device in which a switch circuit is combined, an image signal generated in each device is sequentially read out by a switch operation. The subject image is recorded in the memory. At this time, MOS
Image signals stored in the image sensor can be sequentially read out for each horizontal or vertical line.

[0003]

However, when a moving subject is photographed using a focal plane shutter, "moving body distortion" occurs in the subject image. However, the moving direction of the slit in the focal plane shutter and the image signal from the MOS type image pickup device. If the scanning directions at the time of reading are not the same, the moving object distortion of the subject image will be different, and the image recorded on the silver halide film and the image recorded on the memory will not match.

SUMMARY OF THE INVENTION An object of the present invention is to provide a camera photographing operation control device capable of recording a subject image having the same moving object distortion in a silver halide film and a memory when photographing a moving subject.

[0005]

According to the present invention, there is provided a photographing operation control apparatus for a camera, comprising: photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film; Imaging means for sequentially reading the image signal generated in the image sensor by photoelectric conversion line by line, and driving the shutter for exposure to the silver halide film,
A shutter drive control unit for controlling the movement of the slit through which light guided from the subject passes; and a unit for matching a scanning direction for reading out an image signal and a movement direction of the slit in the shutter during photographing. .

It is desirable that the subject image formed on the image sensor be stored in a memory as digital image data.

The shutter drive control means drives a front curtain and a rear curtain constituting a shutter by a shutter drive circuit, and performs exposure of the silver halide film by moving a slit formed by the front curtain and the rear curtain. Claim 1.
4. The photographing operation control of the camera described in 4.

The scanning direction for reading out the image signal and the moving direction of the slit are in the direction from above to below or below from above, or from left to right or right to left on the silver halide film surface and the image pickup device. 2. The apparatus according to claim 1, wherein the control unit includes a camera.

A photographing operation control device for a camera according to the present invention comprises: a photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film; an image pickup device for forming the subject image; Imaging means for sequentially reading image signals generated in the element line by line; shutter drive control means for driving a shutter for exposure to a silver halide film and controlling movement of a slit for transmitting light guided from a subject; Means for matching the scanning direction for reading the image signal with the moving direction of the slit in the shutter, and means for matching the scanning speed for reading the image signal generated in the image sensor and the moving speed of the slit in the shutter during shooting. It is characterized by having.

A photographing operation control device for a camera according to the present invention comprises: a photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film; a subject image formed on an image pickup device; Imaging means for sequentially reading image signals generated in the element line by line; shutter drive control means for driving a shutter for exposure to a silver halide film and controlling movement of a slit for transmitting light guided from a subject; Means for matching a scanning direction for reading an image signal and a moving direction of a slit in a shutter, and a means for matching a scanning speed for reading an image signal generated in an image sensor and a moving speed of a slit in the shutter during photographing; Means for matching the time during which the imaging device is exposed and the time during which the silver halide film is exposed during photographing. It is characterized in.

A photographing operation control device for a camera according to the present invention comprises: a photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film; an image pickup device for forming the subject image; Imaging means for sequentially reading image signals generated in the element for each line, shutter drive control means for driving a shutter for exposure to a silver halide film, and controlling movement of a slit through which light of a subject passes, Means for matching the scanning direction for reading the image signal generated in the image sensor with the moving direction of the slit in the shutter, and the means for matching the scanning speed for reading the image signal generated in the image sensor and the moving speed of the slit in the shutter during photographing Means for matching the time during which the image sensor is exposed and the time during which the silver halide film is exposed during photographing Characterized by comprising a.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an external view of a silver halide digital still compatible camera to which the first embodiment of the present invention is applied.

When the camera body 11 is viewed from the front, a photographing optical system 12 having a photographing lens and the like is provided at the center of the front surface. Release switch 1 on the top of camera body 11
3, an up switch 14, a down switch 15, a mode switch 16, an erase switch 17, and a display unit 22 are provided. The finder 18 is a half mirror 20
And an eyepiece 21 and a MOS type imaging device 19. That is, the light incident on the finder 18 is
Thus, the subject image is formed on the MOS imaging device 19, and the subject image is observed via the eyepiece 21. The image formed on the MOS imaging device 19 is displayed by a liquid crystal display (LCD) 23 provided on the back surface of the camera body 11, that is, on the back cover U.

FIG. 2 is a block diagram showing an electric circuit of the silver halide digital still camera according to the first embodiment. The system control circuit 30 is a microcomputer and controls the entire camera.

When the release switch 13 (see FIG. 1) is fully depressed, the light that has passed through the photographing optical system 12 is moved to the silver halide film F.
, Whereby the subject image is recorded.

The MOS type image pickup device 19 in the finder 18
An image of a subject is formed on the light receiving surface of, and a color image signal corresponding to the subject is generated. The MOS image sensor 19 is an image sensor of an address reading system, and is controlled by a MOS drive circuit 31 to read an image signal. The image signal read from the MOS image sensor 19 is output to the A / D converter 3
At 3, an analog signal is converted into a digital signal.

When a moving image is displayed on the LCD 23, the image signal converted into a digital signal is sent to the signal processing circuit 34 as it is. The signal processing circuit 34 performs image signal processing such as converting an image signal output from the MOS image sensor 19 into a luminance signal and a color difference signal. The digital signal processed by the signal processing circuit 34 is directly sent to a D / A converter 35, where the digital signal is converted into an analog signal.

This analog signal is processed by the LCD drive circuit 36, and the image signal of the subject is sent to the LCD 23. When the backlight 38 is turned on,
The moving image is displayed on the LCD 23. Backlight 38
Is controlled by the backlight drive circuit 39.

When the release switch 13 is pressed to record a still image in the flash memory 42, electric charges are newly stored in the MOS type image pickup device 19. The charges accumulated for the exposure time are sequentially read out as image signals from the MOS type imaging device 19, sent to the A / D converter 33, and subjected to predetermined processing.
0 is stored. The image signal is sent from the field memory 40 to the signal processing circuit 34, where it is converted into a luminance signal, a color difference signal, and the like.

The converted image signal is compressed in the system control circuit 30, and the compressed image signal is stored in the flash memory 42 as image data. The control of writing and reading of image signals to and from the field memory 40 is performed by a field memory controller 41, and the control of writing and reading of compressed image signals to and from the flash memory 42 is performed by the flash memory controller 43.

The stored image data is read from the flash memory 42, expanded in the system control circuit 30, and temporarily stored in the field memory 40. The image data stored in the field memory 40 is
The signal is sent to the D / A converter 35 and converted from a digital signal to an analog signal. The converted image signal is processed by the LCD drive circuit 36 and sent to the LCD 23. Through these series of operations, the still image data stored in the flash memory 42 is reproduced on the LCD 23.

The timing generator 44 controls the MOS drive circuit 31 and A
/ D converter 33, signal processing circuit 34, D / A converter 3
5. By outputting a sample pulse or the like to the LCD drive circuit 36 and the field memory controller 41,
These operations are controlled.

The system control circuit 30 includes an up switch 14, a down switch 15, a mode switch 16, an erase switch 17, a release full-press switch 45, a release half-press switch 46, a power switch 47, and a back cover switch 4.
8 are connected. Further, the power supply circuit 57 and the display unit 22 are connected to the system control circuit 30, and the number of shots and the like are displayed on the display unit 22.

A focal plane shutter S and a lens (not shown) in the photographing optical system 12 are provided with a shutter driving circuit 5.
9 and the lens drive circuit 50 respectively.
The exposure time is adjusted by the operation of the focal plane shutter S, and the lens drive circuit 50 performs focus adjustment and the like during the distance measurement operation. The aperture drive circuit 49 controls the aperture Q.

The imprint circuit 51 imprints the date of photographing on the image recorded on the silver halide film F.

In the strobe circuit 52, strobe light emission control is performed. In the photometric circuit 53, the brightness of the subject is obtained based on the amount of light detected by a photometric sensor (not shown). In the distance measurement circuit 54, the distance from the camera to the subject is obtained based on the distance measurement data detected by a distance measurement sensor (not shown).

In the frame number detecting circuit 55, the feeding amount of the silver halide film F is detected by counting the perforations of the silver halide film F.

In the film winding / rewinding drive circuit 56,
The winding and rewinding operations of the silver halide film F are controlled.

Referring to FIGS. 3 and 4, the operation of the focal plane shutter S during exposure and the MOS type image pickup device 19 will be described.
Will be described.

As shown in FIG. 3, the focal plane shutter S includes a front curtain SA and a rear curtain SB. When photographing at low and medium shutter speeds, the first curtain A first moves from one end to the other end of the silver halide film F surface, and after the exposure time elapses, the second curtain SB moves from one end to the other end. On the other hand, when shooting at a high shutter speed, the slit M formed between the front curtain SA and the rear curtain SB moves in parallel from one end of the surface of the silver halide film F to expose the silver halide film F. You. That is, the first curtain SA first moves at the same time as the start of exposure, and the second curtain SB starts to move after a delay of the slit interval. In this embodiment, the slit M moves downward from above the silver halide film F.

Such a focal plane shutter S
When but operating, the exposure time in the silver halide film F surface T _B
Is represented by the following equation (1). However, w is the slit width of the shutter, v is the moving speed of slit, ds is the distance from the silver halide film F faces to the slit, it is F _n is aperture value (F-number).

T _B = (w + ds / F _n ) / v (1)

On the other hand, the MOS type image pickup device 1 shown in FIG.
In No. 9, a photosensitive portion cell is formed by a combination of a photodiode D as a photoelectric conversion element and a MOS transistor having a switching function. Here, a 3 × 3 two-dimensional array is shown as a simple example.

When a reset pulse generated by the reset pulse circuit is applied to the cell, charge (image signal) starts to be accumulated in the photodiode D. When a pulse generated by the horizontal or vertical shift register is applied to the cell, the horizontal or vertical MOS switch is turned on, and the stored charge is read as an image signal.
For example, a horizontal MOS switch X and a vertical MOS switch Y
Is turned on, an image signal generated in the cell P is read. Then, by sequentially reading (scanning) the image signals generated for each cell, an image signal for one image is obtained. The time during which the electric charge is accumulated is the exposure time, and the exposure amount is adjusted by a so-called electronic shutter.

At this time, the order of reading image signals is as follows.
For example, if the cell on the line L indicated by the mesh line is scanned first, and after the scanning of the line L is completed, the next lower line is scanned, the MOS type imaging device 19 is sequentially exposed for each line. Will be. The line scanning direction of such an image signal is determined by the slit M of the focal plane shutter S.
Corresponding to the direction of movement.

FIG. 5 shows an image having a moving object distortion. The scanning direction in which the image signal is read in the first embodiment will be described with reference to FIG. However, the moving direction of the slit M when the focal plane shutter S is operated is from the upper side to the lower side on the silver halide film F surface.

When photographing at a high shutter speed using the focal plane shutter S, the exposure starts at the upper end of the silver halide film F surface and ends at the lower end during exposure, so that the exposure timing differs between the upper end and the lower end. . Therefore, when photographing the moving subject A, the recorded subject image has image distortion, that is, moving object distortion. This moving body distortion is shown in an image (C), and a vertically standing subject A is recorded as an oblique subject image.
That is, the upper end portion A1 of the subject A is recorded at the position C1, but the lower end portion A2 of the subject A is recorded at the position C2 because the subject A is moving while the slit M is moving. .

However, the focal plane shutter S
When the moving direction of the slit M formed at the time of operation is from above to below, while the scanning direction when reading an image signal from the MOS image sensor 19 is from below to above,
A subject image having a moving object distortion different from that of the image (C) is recorded in the flash memory 42 (image (B)).
reference).

Therefore, in order to make the moving body distortion of the silver halide film F and the subject image recorded in the flash memory 42 coincide with each other, in the first embodiment, the MOS transistor is set so as to correspond to the moving direction of the slit M from above to below. Type image sensor 1
The scanning direction for reading the image signal from No. 9 is set to a direction from above to below.

FIG. 6 is a timing chart showing a photographing operation and a storing operation in the first embodiment for recording an image on the silver halide film F and the flash memory 42. The photographing operation and the storing operation will be described with reference to FIG.
However, it is assumed that cells for N lines are arranged in the MOS image sensor 19.

When the release switch 13 is half-pressed and the half-release switch 46 is turned on, a series of photographing operation and storing operation are started (reference S101). Then, the brightness of the subject is measured by the photometry circuit 53 (reference S103), and the distance to the subject is measured by the distance measurement circuit 54 (reference S104). Exposure amounts (aperture value and exposure time) are obtained based on the measured brightness of the subject (reference S105).

When the release switch 13 is fully pressed and the release full-press switch 45 is turned on (reference S10).
2) First, an aperture value is determined based on the obtained exposure amount, and the aperture drive circuit 59 narrows the aperture Q to a predetermined open state. Then, the focal plane shutter S is driven by the shutter drive circuit 59, and the front curtain SA starts to move (reference S119).

At the same time, the first
A pulse signal is sent from the reset pulse circuit to the cells on the line, whereby electric charge starts to be accumulated in each cell on the first line (reference S107). When the reset pulse is sent to all the cells on the first line, the reset pulse is sent to the next cell on the second line, whereby the charge on the cells on the second line starts to be accumulated (reference S1).
08). Similarly, the third line,.
A reset pulse is sequentially sent to the cells up to the 2nd line, the (n-1) th line, and the nth line, whereby charges are sequentially accumulated in the cells of each line (reference numerals S112, S11).
3, S114, S115). In addition, from the first line to the n-th line
The time required for the reset pulse to be sent by the line is referred to as a scanning time T _C.

The exposure time T _B since the start of the movement of the first curtain SA
, The trailing curtain SB starts to move (reference S12).
0). Then, the surface of the silver halide film F is exposed in accordance with the movement of the slit M, and the rear curtain SB moves the slit M in the moving time T _F
By moving, a subject image is recorded on the silver halide film F. The exposure time T _B is calculated from equation (1).

On the other hand, when the exposure time T _A elapses after the electric charge starts to be accumulated in the elements on the first line of the MOS type imaging device 19, a pulse is sent from the shift register to the cells on the first line. Then, the switch of each cell on the first line is turned on, and the image signal on the first line is read (reference S110). Similarly, when the exposure time T _A elapses after the charge starts to be accumulated, the second and third lines,
... Image signals are read out in the order of the (n-2) th, (n-1) th, and nth lines (reference numerals S111, S112, S11).
6, S117, S118).

When the exposure to the silver halide film F is completed, the film winding / rewinding drive circuit 56 drives the silver halide film F
Is wound up (reference S122). When an image signal for one screen is read from the MOS image sensor 19, the read image signal is temporarily recorded in the field memory 40. Then, the data is sent to the system control circuit 30 and subjected to compression processing, and is stored as image data in the flash memory 42 (reference S121).

When the image is recorded on the silver halide film F and the flash memory 42, a series of photographing operation and storing operation are completed.

As described above, according to the first embodiment, the moving direction of the slit M formed when the focal plane shutter S is operated coincides with the scanning direction when reading out the image signal generated in the MOS type image sensor 19. By photographing the moving subject A, the subject image having the same moving body distortion can be stored in the silver halide film F and the flash memory 4.
2 can be recorded.

Next, a second embodiment will be described. The external view and the block diagram are the same as those of the first embodiment,
Description is omitted.

FIG. 7 shows an image having a moving object distortion. The scanning speed at the time of reading an image signal from the MOS image sensor will be described with reference to FIG. However, the moving direction of the slit M formed when the focal plane shutter S is operated and the scanning direction when reading an image signal from the MOS image sensor 19 are directions from above to below.

When photographing the moving subject A, the moving object distortion of the subject image recorded on the silver halide film F differs depending on the difference in the moving speed of the slit M formed when the focal plane shutter S operates. The moving speed of the slit M is the moving speed of the front curtain SA and the rear curtain SB, and the moving time _TF of the slit M depends on this moving speed.

Similarly, the moving object distortion of the subject image recorded in the flash memory 42 also differs depending on the difference in the scanning speed when reading out the image signal from the MOS type imaging device 19. The scanning speed is a speed at which an image signal is read from cells on each line, and the scanning time T _C is obtained from the scanning speed.

Therefore, the moving speed of the slit M and MO
If the scanning speed when reading an image signal from the S-type image sensor 19 is different, the subject image (image (E)) recorded on the silver halide film F and the subject image (image (D)) recorded on the flash memory 42 Does not match.

Therefore, in the second embodiment, in addition to making the moving direction of the slit M coincide with the scanning direction with respect to the MOS image pickup device 19, the moving speed of the slit M and the scanning speed with respect to the MOS image pickup device 19 are made coincident. I have. Therefore, moving time of the slit M T _F and the scanning speed T _C are equal.

According to the second embodiment, when a moving subject A is photographed, a subject image having similar moving object distortion can be recorded in the silver halide film F and the flash memory 42.

Next, a third embodiment will be described. The external view and the block diagram are the same as those of the first embodiment,
Description is omitted.

FIG. 8 shows a blurred subject image. The exposure time in the MOS imaging device will be described with reference to FIG. However, the moving direction of the slit M formed when the focal plane shutter S is operated and the scanning direction when reading an image signal from the MOS image sensor 19 are directions from above to below.

[0058] When the focal plane shutter S, exposure time T _B (shutter speed) by adjusting the width of the slit M which is formed during exposure varies.
Generally, when photographing a moving subject A, the recorded subject image is blurred. For example, a subject A having a width K
(See image (G)). Then, come also changed shake by the difference in exposure time T _B.
Similarly, the exposure time T in the MOS image sensor 19
_A , that is, the difference in the charge accumulation time also causes a difference in the blur of the recorded subject image.

Therefore, if there is a difference between the exposure time T _B for the silver halide film F and the exposure time T _A for the MOS type imaging device 19, the subject image (image (G)) recorded on the silver halide film F and the flash memory The subject image (image (F)) recorded in 42 does not match.

Therefore, in the third embodiment, the slit M
The moving direction and the scanning direction with respect to the MOS
In addition to the above, when exposing to the silver halide film F
Interval T _BAnd exposure time T for MOS image sensor_AMatch
Let me. However, the sensitivity of the MOS image sensor 19 and the silver
Here, the sensitivities of the salt films F are in agreement.

According to the third embodiment, when a moving subject A is photographed, a subject image having the same moving object distortion can be recorded in the silver halide film F and the flash memory 42.

Next, a fourth embodiment will be described. The external view and the block diagram are the same as those of the first embodiment,
Description is omitted.

FIG. 9 shows a subject image recorded in the fourth embodiment.

In the fourth embodiment, the moving direction of the slit M formed when the focal plane shutter S is actuated matches the scanning direction at the time of reading an image signal from the MOS image sensor 19, and the moving speed of the slit M And MOS
Speed for scanning type image sensor 19 (ie, moving time T
_F and the scanning time T _C ), the exposure time T _B for the silver halide film F, and the exposure time T _A for the MOS image sensor also match. Therefore, when photographing the moving subject A, the subject image (image (I)) recorded on the silver halide film F and the subject image (image (H)) recorded on the flash memory 42 match.

FIG. 10 is a timing chart when the photographing operation and the storing operation are executed in the fourth embodiment.

In the fourth embodiment, unlike the first embodiment, the exposure time T _A and the exposure time T _B match, and the scanning time T _C and the movement time T _{F of the} slit M also match.
The procedures of the photographing operation and the storing operation at the time of photographing are the same as in the first embodiment.

As described above, according to the fourth embodiment, when photographing a moving subject A, a subject image having the same moving object distortion can be recorded in the silver halide film F and the flash memory 42.

In the first to fourth embodiments, the moving direction of the slit M and the scanning direction with respect to the MOS type image pickup device 19 are directed from above to below. However, the present invention is not limited to this. That is, the direction may be from downward to upward, from left to right, or from right to left.

In the case of an image sensor of an address reading system for sequentially reading image signals accumulated in each cell, M
It may be applied in place of the OS type imaging device 19.

[0070]

As described above, according to the present invention, when a moving subject is photographed, a subject image having the same moving object distortion can be recorded in each of the silver halide film and the memory.

[Brief description of the drawings]

FIG. 1 is an external view of a silver halide digital still dual-use camera according to first to fourth embodiments.

FIG. 2 is a block diagram showing an electric circuit of the silver halide digital still dual-use camera according to the first to fourth embodiments.

FIG. 3 is a diagram showing an operation of a focal plane shutter;

FIG. 4 is a diagram illustrating an operation of reading an image signal from a MOS type imaging device.

FIG. 5 is a diagram showing a subject image having moving body distortion recorded when a moving subject is photographed.

FIG. 6 is a timing chart showing a procedure of a photographing operation and a storing operation in the first embodiment.

FIG. 7 is a diagram showing a subject image having moving body distortion recorded when a moving subject is photographed.

FIG. 8 is a diagram showing a subject image having blur and moving object distortion recorded when a moving subject is photographed.

FIG. 9 is a diagram showing a subject image having moving body distortion recorded when a moving subject is photographed.

FIG. 10 is a timing chart showing a procedure of a photographing operation and a storing operation in a fourth embodiment.

[Explanation of symbols]

 19 MOS type imaging device (imaging device) F Silver halide film M Slit S Focal plane shutter (shutter)

Continued on front page F term (reference) 2H054 BB07 CD03 2H081 AA00 AA01 AA66 CC00 CC51 DD00 5C022 AA13 AB27 AB31 AB51 AC00 AC03 AC52 AC69 AC80 5C024 BA01 CA06 GA26 GA51 GA52 JA10 JA31

Claims (7)

[Claims] 1. A photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film, an object image being formed on an image sensor, and an image signal generated in the image sensor by photoelectric conversion. Imaging means for sequentially reading out each line, shutter drive control means for driving a shutter for exposure to the silver halide film and controlling movement of a slit for passing light guided from a subject, And a means for matching a scanning direction for reading the image with a moving direction of the slit in the shutter. 2. The apparatus according to claim 1, wherein the subject image formed on the image sensor is stored in a memory as digital image data. 3. The shutter drive control means drives a front curtain and a rear curtain constituting the shutter by a shutter driving circuit, and moves the slit formed by the front curtain and the rear curtain to move the silver halide. 2. The photographing operation control device for a camera according to claim 1, wherein the film is exposed. 4. A scanning direction for reading out the image signal and a moving direction of the slit, from above and below or above and below, or from left and right or right on the silver halide film surface and the image pickup device. The photographing operation control device for a camera according to claim 1, wherein the direction is a leftward direction. 5. A photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film, forming the subject image on an image sensor, and converting an image signal generated in the image sensor by photoelectric conversion. Imaging means for sequentially reading out each line, shutter drive control means for driving a shutter for exposure to the silver halide film and controlling movement of a slit for passing light guided from a subject, Means for matching the scanning direction for reading the image with the moving direction of the slit in the shutter; and means for matching the scanning speed for reading the image signal generated in the image sensor and the moving speed of the slit in the shutter during photographing. A photographing operation control device for a camera, comprising: 6. A photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film, forming the subject image on an image sensor, and converting an image signal generated in the image sensor by photoelectric conversion. Imaging means for sequentially reading out each line, shutter drive control means for driving a shutter for exposure to the silver halide film and controlling movement of a slit for passing light guided from a subject, Means for matching the scanning direction for reading the image with the direction of movement of the slit in the shutter; and means for matching the time during which the image sensor is exposed and the time during which the silver halide film is exposed during photographing. A photographing operation control device for a camera. 7. A photographing operation control means for controlling a photographing operation for recording a subject image on a silver halide film, forming the subject image on an image sensor, and converting an image signal generated in the image sensor by photoelectric conversion. Imaging means for sequentially reading out each line, shutter drive control means for driving a shutter for exposure to the silver halide film and controlling movement of a slit for passing light guided from a subject, Means for matching the scanning direction for reading the image with the moving direction of the slit in the shutter; and means for matching the scanning speed for reading the image signal generated in the image sensor and the moving speed of the slit in the shutter during shooting. At the time of shooting, the time during which the image sensor is exposed and the time during which the silver halide film is exposed are matched Camera imaging operation control apparatus characterized by comprising a stage.