JPH07283982A - Video integrated camera - Google Patents

Abstract

PURPOSE:To use properly a video monitoring function to display a moving image in recording and a camera monitoring function to confirm a photographic image on a photosensitive member such as photosensitive film corresponding to an application purpose. CONSTITUTION:A camera main body provided with a photographic lens part performs photography on silver salt film and image pickup on a CCD 43 by separating a luminous flux by a half mirror in the inside. An image image- picked up by the CCD 43 is displayed on a monitor 47. Also, a magnetic recording medium recordable the moving image Image-picked up by the CCD 43 is loaded on the lover part of the camera main body. A microcomputer(muC2) 100 monitordisplays a photographic plan on the silver salt film and the image after photographing in a still picture, and monitor-displays the moving image in recording. The monitor display of the still picture and that of the moving image on the monitor 47 can be performed by switching appropriately replying to the operations of a recording start switch SREC and a pre-view switch SPV.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an integrated type camera having a camera capable of photographing on a photosensitive film and a video camera for photographing a subject image obtained through an image pickup member, and more particularly, to an image pickup. The present invention relates to a video-integrated camera having a function of displaying (confirming) a subject image obtained via a member.

[0002]

2. Description of the Related Art In recent years, there has been proposed a video-integrated camera capable of taking a picture at the same time as a photo opportunity while taking a video (Japanese Patent Laid-Open No. 274033/1993).
JP-A-5-199441). This kind of camera
Behind the taking lens, a photosensitive film and an image pickup member are arranged at positions where the subject images shunted via a half mirror are guided respectively. A magnetic recording medium is connected to the image pickup member, and the image signal converted by the image pickup member can be continuously written and recorded on the magnetic recording medium. The subject image can be taken by being guided to a photosensitive film through a shutter. Photographing on the photosensitive film can be performed even during movie recording on the magnetic recording medium, that is, at the same time as video recording.

Further, in a camera having a monitor for selectively displaying, as a moving image or a still image, an image taken by an image pickup member through a taking lens, the operation of a release button is invalidated while the still image is being displayed. Are known (Japanese Patent Laid-Open No. Sho 64)
-41578 gazette).

Further, there are commercially available video cameras for selectively displaying moving images and still images on a monitor.

[0005]

The above-mentioned conventional video-integrated camera has a structure in which a video camera and a photographing optical system for a photosensitive film are integrated so that photographing on the photosensitive film and video photographing can be performed simultaneously / selectively. However, it does not have a function or configuration for confirming a photographed image on a photosensitive film, that is, for displaying a photographed image or a photographed image on a monitor. Further, the camera described in Japanese Patent Laid-Open No. 64-41578 has only a monitor for displaying a moving image / still image, and does not have a video function or configuration for recording a moving image. Further, the above-mentioned video cameras on the market do not have a photographing function and a structure for a photosensitive film. Therefore, there is no concept of the monitor function of confirming the photographed image on the photosensitive film.

The present invention has been made in view of the above,
A video that selectively displays a moving image display on the monitor of a moving image being recorded and a captured image on a photosensitive member such as a photosensitive film, that is, a still image display on the monitor, which shows a shooting schedule and the captured image as a still image. An object is to provide a body camera.

[0007]

SUMMARY OF THE INVENTION The present invention provides a photosensitive medium on which an image of one light flux, which is a light flux that has passed through a photographic lens and which is bisected, and an image of the other light flux. An image pickup member for picking up an image, a display member for displaying an image picked up by the image pickup member on a monitor, and an image picked up by the image pickup member at an arbitrary timing so as to confirm a picked-up image on the photosensitive medium. Still image display means for displaying the moving image, moving image recording means for repeatedly capturing an image of the imaged member at a predetermined cycle and sequentially recording the captured images on a moving image recording medium, and displaying a recorded image on the moving image recording medium as a moving image. It is provided with a moving image display means and a display selection means for selectively performing the still image display and the moving image display.

[0008]

According to the present invention, the light flux passing through the taking lens is divided into two, and the image formed by one light flux is guided to a photosensitive medium such as a silver salt film to be exposed, that is, photographed. The image composed of the other light flux is guided to the image pickup member and is picked up. The image picked up by the image pickup member can be displayed on the display member.
The display of the image on the display member confirms the photographed image on the photosensitive medium, that is, the photographing schedule and (that is, and / or)
A still image display is performed to confirm whether or not an image after shooting is desired, and a moving image display when sequentially storing optical images repeatedly captured by the image capturing member in a moving image recording medium. The display selection means prohibits the moving image display operation during the still image display operation, while prohibiting the still image display operation during the moving image display operation.

[0009]

2 to 4 show an example of the external structure of a video-integrated camera to which the present invention is applied. FIG. 2 is a front perspective view, FIG. 3 is a rear perspective view, and FIG. FIG. The camera has a main structure including a camera body 20 and an electronic information recording unit 50 that is integral with or detachable from the camera body 20, and the camera body 20 has an integral or replaceable photographing lens unit 21. Is provided, and a grip portion 22 is formed at a position where the photographer grips the left and right sides.

Various operation members and other members are arranged on the upper surface of the camera body 20 side. Reference numeral 23 denotes a release button. When the first step is pressed, a switch S ₁ for shooting preparation, which will be described later, is turned on to start various operations such as photometry, exposure calculation and AF. The switch S ₂ for turning on is started and the exposure control operation is started.

Reference numeral 24 denotes a body display section composed of a liquid crystal panel or the like for displaying a shutter speed, an aperture value and the like. A display operation member 25 outputs an instruction signal for displaying the display data stored in the internal memory (see FIG. 14) in the camera body 20 on a monitor 47 (see FIG. 14) including a color liquid crystal panel described later. Is. 26
Is a frame memory in the camera body 20 (see FIG. 14)
It is a memory change switch that is operated when changing the image stored in. A flash (not shown) can be attached to the head of the camera body 20 as needed.

The electronic information recording section 50 is arranged at a portion such as the lower portion of the camera body 20 where there is little hindrance to the camera operation, and an electric memory for electrically recording a still image stored in a frame memory in the camera body 20. IC card 51 as
A mounting portion 50a into which a tape can be loaded, an unillustrated mounting portion into which a magnetic recording medium 52 such as a magnetic tape or a magneto-optical disk capable of recording a moving image can be loaded, and a tape feed drive portion are internally provided. There is.

Reference numeral 33 denotes a front dial which is provided at an appropriate position on the front surface of the grip portion 22 and is rotated when changing the numerical value of the photographing information. A rear dial 34 is provided at a proper position on the back side of the camera body 20 and has the same function as the front dial 33. The switches 35 to 37 are provided on the upper surface of the camera body 20. A color correction switch 35 is operated to perform color correction while looking at the monitor 47.
Reference numeral 36 denotes an exposure change switch that is operated for exposure correction in shooting under constant light, and 37 is an exposure change switch that is operated for exposure correction of the flash light amount in flash shooting, and each of these switches 35 to 37. Is operated, the front dial 33 or the rear dial 34
When is rotated, the numerical values of the parameters for correction and change are changed. 38 is also the camera body 20
Is provided on the upper surface of the camera and the exposure mode (P, A, S,
The exposure mode change switch is operated when instructing the change of M). With the exposure mode change switch 38 operated, the front dial 33 or the rear dial 3
When 4 is rotated, the exposure mode is changed.

Reference numeral 39 is a recording start switch operated when recording a moving image, 40 is a film photographing mode for recording a still image on a photosensitive film, electronic still photographing mode for recording a still image on an IC card 51, and a magnetic recording medium 52. It is a shooting mode change switch for changing a combination of three kinds of shooting modes of a moving picture shooting mode for recording a moving picture.

A preview switch 27 is provided at an appropriate place outside the photographing lens unit 21. The preview switch 27 is an operation member for displaying on the monitor 47 the subject image captured by passing through the aperture set to the control aperture value.

As shown in FIG. 3, a finder 28 for a monitor 47 is provided above the back surface of the camera body 20. An eyepiece sensor 29 in which a light emitting element 291 such as an LED and a light receiving element 292 such as an SPC (silicon photocell) are arranged adjacent to each other is provided at a position close to the finder 28. This eyepiece sensor 29 is
It detects whether or not the photographer is looking through the viewfinder, and the eyepiece detection can be performed by the light emitted from the light emitting element 291 being reflected by the face of the photographer looking through the viewfinder and received by the light receiving element 292. It is like this.

Reference numeral 30 is a line-of-sight operation member for setting (setting) and resetting the line-of-sight of the photographer detected by the line-of-sight detection circuit 2 described later, that is, the line-of-sight area within the angle of view.

The outside of the grip portion 22 is covered with a cover 220 made of rubber having elasticity, and electrically conductive patterns 221 and 222 insulated from each other are arranged inside the grip portion 22 as shown in FIG. ing. A conductive rubber (not shown) is arranged between the rubber 220 and the conductive patterns 221 and 222. The outer cover 220 of the grip portion 22 is configured to be electrically connected to the conductive patterns 221 and 222 via the conductive rubber by pressing the outer cover 220 with a hand to grip the camera. With this configuration, the grip portion 22 functions as a grip switch S _G.

FIG. 5 shows transceivers TX and R for image transmission.
In the external view showing X, (a) shows the transceiver TX on the camera body 20 side, and (b) shows the remote control transceiver RX. The transceivers TX and RX are attachable to the camera body 20 in consideration of portability and the like. 6 and 7
[Fig. 3] is a front perspective view and a rear perspective view of the camera body 20 with the transceivers TX and RX attached. Transceiver TX
Has a side surface shape that matches the shape of the right side surface when viewed from the front of the camera body 20, and both side surfaces are detachably attached using, for example, the locking member 20a.
The transceiver RX is oriented horizontally on the back surface of the camera body 20 and is detachably attached by a locking member (not shown).

The transmitter / receiver TX, RX has a camera body 2
Switches corresponding to switches that can be operated on the 0 side are provided. That is, T1 is a switch for switching whether to perform remote control by the transceiver TX, and T2 is an antenna for performing signal transmission with the transceiver RX. Further, in the transceiver RX, R1 is a power switch, R2 is a release instruction button corresponding to the release button 23, and R3 is an exposure mode change switch corresponding to the exposure mode change switch 38. The two switches of R4 are up / down switches corresponding to the front dial 33,
Two switches R5 are up / down switches corresponding to the rear dial 34, R6 is a preview switch corresponding to the preview switch 27, R7 is an exposure change switch with constant light corresponding to the exposure change switch 36, and R8 is a monitor 47. A two-dimensional color liquid crystal display unit having the same function as the above, R9 is an antenna for performing signal transmission between the transceiver and the TX, and R10 is an exposure change switch of the flash light amount corresponding to the exposure change switch 37. Transceiver T
When X is attached to the camera body 20, a preview can be performed by the color liquid crystal display unit R8 of the transceiver RX without looking through the finder. R11 is a recording start switch corresponding to the recording start switch 39, and R12 is a shooting mode change switch corresponding to the shooting mode change switch 40. Regarding the control of transceivers TX and RX,
It will be described later.

FIG. 8 is a diagram showing an internal structure relating to the taking lens 211 and the optical system in the camera body 20. In the camera body 20, a mirror 42 for separating a part of the light flux fixed with respect to the optical axis 41 of the taking lens 211 is provided.
Are arranged. The mirror 42 is a half mirror and is composed of an extremely thin pellicle mirror, and guides a part of the light flux passing through the photographing lens 211 to the CCD 43 as an area sensor via the reduction optical system 44. The CCD 43, which is the area sensor, detects focus (A
F), which performs photometry and dimming. Also, the mirror 42
Is fixed even during photographing, and the optical image that has passed through the photographing lens 211 is guided to a photosensitive film 45 such as a silver salt film in the rear through a focal plane shutter 46 disposed in front of the photosensitive film 45.

The CCD 43 is composed of solid-state image pickup devices arranged in a matrix, and R, G, and B color filters are provided correspondingly on the front surface, and the light image passing through the half mirror 42 is color-picked up. is there.

FIG. 9 is a structural diagram showing an example of the CCD 43. In FIGS. 9A and 9B, reference numeral 431 is a photosensitive layer having a lattice shape, and the photosensitive pixels 432 are arranged between the photosensitive pixels 432 arranged in a matrix. Similarly, it is mounted on the insulating film 433 and electrically insulated from the photosensitive pixel 432. Further, as shown in FIG. 6C, the photosensitive layer 431 is divided into a plurality of sections, for example, a central section 431a and a peripheral section 431b to form a photometric pattern. Then, based on the photometric signals from both of the sections 431a and 431b, for example, switching between center-weighted photometry and average photometry is possible. As will be described later, the CCD 43 is divided into 15 areas that are electrically connected to each other, and the photometry and the dimming are performed in combination. By configuring the CCD 43 in this way, of the light that enters the CCD 43, the light that enters the photosensitive pixels 432 is photoelectrically converted and accumulated in each photosensitive pixel 432, and the accumulated charges are transferred to form image data. On the other hand, the light that is taken out and is incident on the grid-shaped photosensitive layer 431 is converted into a photometric signal in each area corresponding to the brightness of the entire image and is output.

Returning to FIG. 8, the monitor 47 is composed of a two-dimensional color LCD or the like, and is an image picked up by the CCD 43.
Alternatively, it displays a stored image such as a frame memory described later. In addition to the above image display, the monitor 47 displays required marks, shutter speed Tv, and aperture value Av.
The shooting conditions, etc., can be displayed in a superimposed manner. Reference numeral 471 is a backlight for the light source of the monitor 47. Reference numeral 49 is an eyepiece lens which allows the image displayed on the monitor 47 to be observed through the viewfinder 28.

The optical member 48 has a surface 481 which reflects the measuring spot light for detecting the visual axis and transmits the image light from the monitor 47.

The line-of-sight detection circuit 2 is for detecting the line-of-sight position of the photographer looking into the finder 28. The line-of-sight detection circuit 2 includes an infrared LED, a half mirror for switching the optical paths in the reciprocating path, and line-of-sight areas AR1 to AR16 described later. Split formation (see Figure 10)
It is composed of an infrared area sensor. Infrared rays are used to eliminate the effects of sunlight.
The line-of-sight detection is such that the light emitted from the infrared LED is reflected by the eyes of the photographer looking into the finder 28 and returns, and the line-of-sight area of the infrared area sensor is used to make a determination. . For example, a known line-of-sight detection method performed by using the first Purkinje image, or by using the first Purkinje image and the fourth Purkinje image, or another known method may be adopted.

FIG. 10 shows the line-of-sight area and the corresponding positional relationship between the line-of-sight area and the areas of AF, photometry, and light control.

As shown in the figure, the line-of-sight detection area frame 19
Indicates a range in which the line of sight can be detected. The line-of-sight area is approximately in the center of the photographing screen frame 18, corresponds to an area ratio of 1/2, and is further divided into 3 rows and 5 columns. Are formed. Therefore, the gaze detection is the first to fifteenth.
This is performed by determining in which of the 15 line-of-sight areas (AR1 to AR15) the reflected light from the photographer's eye is received. The area AR16 is an area outside the line-of-sight detection area frame 19.

Focus detection areas AF1 to AF15 (not shown) are set to positions corresponding to AR1 to AR15 of the line-of-sight area. In addition, the photometric area AE
1 to AE15 (not shown) are also in the above areas AR1 to AR15
The position is set to correspond to.

FIG. 11 is a diagram showing marks and the like that can be displayed on the monitor 47. The line-of-sight detection area frame 19 and the frames of the respective line-of-sight areas AR1 to AR16 can be displayed. Further, a display area for four digits for displaying Tv and a display area for two digits for displaying Av are provided in the lower portion outside the line-of-sight detection area frame 19. At the upper left of the line-of-sight detection area frame 19, a display unit for setting the photographing modes 1 to 3 and the post-confirmation display mode 4 is provided. As shown in the figure, shooting mode 1 is a film shooting mode, shooting mode 2 is an electronic still shooting mode, and shooting mode 3 is a moving image shooting mode.

In the mode display, only the mode selected and set is displayed. For example, when only the moving image shooting mode 3 is selected, only the mark indicating the magnetic storage medium 52 is displayed. On the other hand, for example, shooting modes 1 to 3
When all of are selected, they are all displayed. The mark indicating the post-confirmation display mode 4 is displayed when the still image display mode is selected. When a specific mode is not selected, for example, when a photosensitive film (hereinafter, referred to as a silver salt still photography mode) and an electronic still photography mode are not selected, for example, the switch S ₁ is pressed to instruct them. When the switch is turned on, the marks representing the unselected silver salt still shooting mode 1 and electronic still shooting mode 2 blink.

Further, the shutter speed TV and the aperture value A
As for the display of V, the shutter speed TV and the aperture value AV are displayed regardless of whether or not shooting is performed when the silver salt still shooting mode and the electronic still shooting mode are selected. On the other hand, when neither the silver salt still shooting mode nor the electronic still shooting mode is selected, that is, when only the moving image shooting mode is selected, neither the shutter speed TV nor the aperture value AV is displayed. As a result, unnecessary displays are turned off, which eliminates the annoyance on the screen and saves power.

FIG. 12 is a diagram showing a state where the line-of-sight detection area frame 19 is displayed on the monitor 47, and FIG. 13 is a diagram showing a state where the line-of-sight area is displayed on the monitor 47. That is, the line-of-sight detection area frame 19 is displayed as shown in FIG. 12 or the frame indicating the detected area AR is displayed as shown in FIG. 13 based on the line-of-sight detection result. In FIG. 13, the area A currently detected by the line-of-sight detection circuit 2 is detected.
The area R is displayed by blinking in the broken line frame 191 and the detected area A is displayed.
Area A manually set by the line-of-sight operation member 30 from within R
R is lit and displayed in a solid line frame 192. When both areas AR are overlapped with each other, for example, they are displayed in a blinking manner. And AF
The processing and the AE processing including the light control of the flash are performed on the area AR of the solid line frame 192.

FIG. 1 is a circuit block diagram in a camera body to which the present invention is applied. In the figure, reference numeral 1 is a microcomputer (hereinafter referred to as a microcomputer (μC1)), which has an internal RAM for taking in signals from various switches and operating members and image signals picked up by the CCD 43, and an internal ROM (not shown). Various calculations and sequence control of the entire camera are performed based on a program written in advance.

The power supply 15 is composed of a battery or the like, and supplies power to a required circuit section at a voltage Vo. A rectifying diode D1 and a backup capacitor C1 are provided between the power supply 15 and the microcomputer (μC1) 1. The switch Q1 is, for example, a CMOS transistor,
As will be described later, it is turned on / off based on a control signal from the microcomputer (μC1) 1, and by this on / off, power is supplied to a required circuit portion at a voltage V ₁ .

The eyepiece detection circuit 3 has the eyepiece detection sensor 29 described above. An exposure drive unit 4 includes an aperture control unit 4a that controls the aperture with a servo type and a shutter control unit 4b that performs shutter control. The winding circuit 5 winds the film 45 and charges a mechanism for photographing (reset to an initial position) in synchronization with the release. A film sensitivity reading circuit 6 (indicated by DX in the figure) reads the data of the film attached to the surface of the cartridge in which the film is loaded, using optical or magnetic means. The film data includes film speed (ISO) and film type (daylight / tungsten / black and white, latitude information, negative / positive).

LEMI 7 is a lens drive circuit for focus detection, and LEMII 8 is a lens drive circuit for image blur correction, which drive the lens through the mount portions of the camera body 20 and the taking lens 211. When measuring ambient light, the photometric and dimming circuit 9 obtains photometric data for each AE area based on the detection signal from the CCD 43, outputs the photometric data to the microcomputer (μC1) 1, and is emitted from the flash and reflected by the subject. Also, when the flash light is measured, a light emission stop signal is output to the flash light emitting circuit 32 in order to control the light emission amount of the flash by the detection signal from the CCD 43. Flash light emitting circuit 32 (FL in the figure)
Is a circuit in the flash that can be attached to and detached from the camera body 20, and the light emission is controlled by a signal from the camera body 20.

The CCD / monitor / recording unit 10 is a CCD 4
3, a microcomputer (μC2) 100 for processing the image signal picked up by the CCD 43, a frame memory for storing the processed image, a monitor 47 for displaying the image in color, a recording unit 16 for controlling the recording operation of the electronic still image, and It is provided with a recording unit 17 for recording a moving image, which will be described in detail later.

The inverter 11 (indicated by INV in the drawing) has a backlight 47 when the monitor 47 is an LCD.
1 is a DC-AC inverter that converts a DC voltage V ₁ into an AC voltage of a required level in order to supply an AC voltage to the AC power supply circuit ₁ .
The encoder 12 (indicated by DV in the figure) is the photographing lens unit 2.
1, which is composed of a bit mark member having a position-coded face-to-face relationship with the stationary side and a rotation side, and a reading member for reading information of each bit of the bit mark member. Output as code data. The encoder 13 (indicated by f in the figure) is composed of a bit mark member and a reading member similar to the above, which are arranged face-to-face with the stationary side and the focus adjusting lens side of the taking lens unit 21, and code data corresponding to the focal length. Output as. The AND circuit 14 has a switch S _{1 at} both input terminals.
Is connected to the grip switch S _GR, and the output side is connected to the interrupt terminal INT of the microcomputer (μC1) 1.

The transmission / reception unit 142 transmits the picked-up image data and various control data to the transceiver RX and also receives signals of various operation switches from the transceiver RX, and the microcomputer (μC1) 1 receives the signals. The transmission / reception operation of the generated signal and the signal to be transmitted is controlled.

Next, various switches will be described.
The switch S ₁ is a switch that starts each operation such as AE and AF calculation for shooting preparation by pressing the release button 23 in the first step. The switch S ₂ is a switch that starts the exposure control operation for release by pressing the release button 23 in the second step. The switch S _DPI is a switch for displaying a still image of the image stored in the frame memory at the time of shooting, and corresponds to the display operation member 25 of FIG. The switch S _PV is a switch for displaying on the monitor the image captured through the aperture set to the control aperture value, and corresponds to the preview switch 27 in FIG. The switch S _SDI is a switch for setting (setting) and resetting the line-of-sight area detected by the line-of-sight detection circuit 2, and corresponds to the line-of-sight operating member 30 of FIG.
The switch S _DPUP is a switch for sequentially changing the designation of the image stored in the internal memory, and corresponds to the memory changing switch 26 of FIG. The switch _SWB corresponds to the color correction switch 35 in FIG. By operating this switch _SWB and the front dial 33, the blue color is corrected, and by the rear dial 34, the red color is corrected. The switch S _X is a switch that is turned on when the first curtain of the focal plane shutter is completed,
When this is turned on, flash light emission is started. The switch S _{(+/-) AMB} is the exposure change switch 36 shown in FIG.
The exposure compensation is performed in accordance with. Switch S
_{(+/-) FL} corresponds to the exposure change switch 37 of FIG. 2 and performs the exposure correction of only the flash light amount. The switch S _MD corresponds to the exposure mode change switch 38 in FIG. 2 and changes the exposure mode. The switch S _REM is a switch that switches between control by the transceiver RX and control by the camera body 20. The transceiver TX is the camera body 20
Mounted on the switch T1 (ie switch
The on / off signal of the switch _REM is input to the microcomputer (μC1) 1 by the operation of ( _REM ). The switch S _REC is operated when recording a moving image, as shown in FIG.
The switch corresponding to the recording start switch 39 of (1) causes interruption when the switch is turned on and recording is started.

The switch S _MDT is a switch corresponding to the shooting mode changing switch 40 of FIG. 2 for switching shooting modes, and can set seven kinds of shooting modes as described later.

Next, FIG. 14 is a detailed circuit configuration diagram of the CCD / monitor / recording unit 10 shown in FIG. CCD /
The monitor / recording section 10 is functionally roughly divided into an image pickup or signal processing section, an image processing section, a recording section and a display section,
The recording portion has various configurations capable of recording moving images and still images. The microcomputer (μC2) 100 outputs a command signal and a control signal to each circuit unit of the CCD / monitor / recording unit 10 and receives data from the microcomputer (μC1) 1 on the main body side to appropriately perform data communication. . The microcomputer (μC21) 120 is for image processing for processing image data.

The CCD 43 is connected to a photometry / dimming signal processing circuit 430 for extracting a signal for photometry and dimming. The signal processing circuit 430 is further connected to the camera body 2.
It is connected to the metering / dimming circuit 9 of 0 and transfers the metering / dimming data as an STP signal.

The timing signal generating circuit (hereinafter referred to as TG1) 101 outputs various timing signals to the required circuit portion of the above-mentioned image pickup or signal processing portion under the control of the microcomputer (μC2) 100. , The timing signal generation circuit (hereinafter referred to as TG2) 102 is
It receives the timing signal from G1 and outputs a predetermined timing signal mainly to the required circuit section of the image processing section described above. The CDS 103 removes noise by performing correlated double sampling processing on image signals of R, G, and B colors from the image pickup signal read from the CCD 43. The WB 104 performs white balance processing based on the data from the microcomputer (μC2) 100. The AGC 105 adjusts the gain based on a signal from the microcomputer (μC2) 100. A / D
The conversion circuit 106 converts the input analog image signal into a digital image signal. The γ circuit 107 performs γ conversion on the image signal. Matrix circuit 108
Is a circuit for converting the γ-converted R, G, and B signals into a Y signal and a color difference signal for display. The AGC 109 adjusts the gain based on the signal from the microcomputer (μC2) 100. The image compression circuit 110 subjects the input moving image signal to image compression processing based on, for example, the MPEG standard. The frame memory 111 is a dual port RAM capable of simultaneous data input / output, and is used for temporary data saving when the image compression circuit 110 compresses data.

The MIC 112 is an audio microphone in which a receiving portion is provided at an appropriate position on the front surface of the camera body so as to efficiently collect ambient sound, and the audio signal is mixed with an audio signal. Amplifier circuit 1
13. After passing through the A / D conversion circuit 114, pulse modulation is performed by the ADPCM circuit 115.

The digital modulation circuit 116 converts the image signal from the image compression circuit 110 and the audio signal from the ADPCM circuit 115 into a required format for recording respectively. The recording head 117 is for recording the format-converted signal on the magnetic recording medium 52. For recording on the magnetic recording medium 52, the recording operation is controlled by a control signal from the microcomputer (μC1) 1. As for each drive mechanism for recording around the recording head 117, a well-known drive mechanism for recording on a magnetic tape, for example, can be adopted.

The frame memories 121 and 122 are dual port RAMs capable of simultaneous data input / output, and perform image writing and image reading. The frame memory 121 stores the original image, and the frame memory 122 stores the image after the original image is image-processed by the microcomputer (μC21) 120. The adder circuit 124 is an adding circuit that adds the original image of the frame memory 121 and the image signal from the matrix circuit 108. The SW 125 captures the image signal from the matrix circuit 108 into the frame memory 121 and adds the image signal to the adder circuit 1.
It is a switch for controlling the lead to the 24 side. Image compression
The decompression circuit 126 subjects the image signals from the frame memories 121 and 122 to predetermined image compression processing based on the JPEG standard. The video reproduction circuit 127 converts the image signals from the frame memories 121 and 122 into a displayable format. The switching circuit 128 is a microcomputer (μC2
1) Based on the signal from 120, the frame memory 12
The image signal from 1,122 is applied to the image compression / expansion circuit 1
26 and the video reproduction circuit 127. The memory 129 is an image memory provided inside, and has a capacity capable of recording images of a required number of frames. The audio signal is reproduced through a modulation circuit 130 and a sound reproduction circuit 131 by a speaker 132 provided at an appropriate place on the surface of the camera body 20. Further, the driver 133 enables the image signal from the video reproduction circuit 127 to be displayed on the monitor 47.

FIG. 15 is a block diagram of the transceiver TX. The power of the transceiver TX can be supplied from the camera body 20 side by connecting a power supply terminal (not shown) when the transceiver TX is attached to the camera body 20. The microcomputer (μC3) 140 controls each part and exchanges signals with the microcomputer (μC1) 1. The memory 141 is a dual port RAM capable of simultaneous data input / output, and receives and stores the output image from the switching circuit 128. The memory 141 writes and reads image data. The transmission / reception unit 142 transmits / receives image data and control data to / from the transmission / reception unit of the transceiver RX and receives operation data from the transceiver RX.

FIG. 16 is a block diagram of the transceiver RX. The microcomputer (μC4) 150 controls each part. The transceiver 151 is a transceiver T of the camera body 20.
The image data and the control data are received from X, and the operation data is transmitted from the transceiver RX. The memory 152 writes the received image data and repeatedly reads it out to the display control circuit 153. The read image data is read by the display control circuit 15 as in the case of the camera body 20.
3, the color LCD 1 constituting the liquid crystal display section R8
It is read out to 54 and displayed as a still image. The timing control circuit 156 is for timing between signals for operating each circuit unit. BL155 is a color LCD 1
54 is a backlight for irradiation.

Next, various switches will be described.
The switch S _RH corresponds to the power switch R1 and switches between supply and cutoff of the power supply E _RM .
The switch S _MD corresponds to the exposure mode change switch R3. S ₁ and S ₂ correspond to the release instructing button R2, and are a half-press for the exposure preparation operation and a full-press for the release. The switch S _PV corresponds to the preview switch R6. The switch S _{(+/-) FL} corresponds to the flash light amount exposure change switch R10. The switch S _{(+/-) AMB} corresponds to the exposure change switch R7 for constant light. Switch (UP / D
N) 1 corresponds to the up / down switch R4, and the switch (UP / DN) 2 corresponds to the up / down switch R5. The switch S _REC is a moving picture recording start switch, and corresponds to the moving picture recording start switch R11. The switch S _MDT is a shooting mode change switch, and corresponds to the shooting mode change switch R12.

FIG. 17 is an internal circuit diagram of the photometric and dimming circuit 9. AR1C to AR15C are areas AR1 to AR
AR1C will be described below because they are photometry circuits for 15 and have the same circuit configuration. SP
C1 is a photometric (dimming) element, which is a circuit representation of one of the 15 areas of the CCD 43, and is connected between both input terminals of the operational amplifier AMP1. The diode D1 is for performing logarithmic compression, and the operational amplifier A
It is provided between the output terminal of MP1 and one input terminal. BUF1 is a buffer, and the expansion transistor Tr1 is connected to the output side thereof. The collector of the extension transistor Tr1 is connected to the output terminal a1 by an operational amplifier AMP1.
The output terminal of is connected to the output terminal b1. The operation of this circuit will be described. The photometric (light control) element SPC1 outputs a current according to the incident light, the output current is compressed by the diode D1, and the output end b is output as a photometric output.
1 to be guided to the microcomputer (μC1) 1. On the other hand, the photometric signal passes through the buffer BUF1 and the extension transistor T
It is expanded at r1 and goes through the output end a1 to the transistor Tr.
21 are input to the base. This transistor Tr21
Has an emitter connected to a constant voltage source, a collector connected to a charging capacitor C, and a base connected to the cathode of a diode D20 connected to the constant voltage source.
Also, AR1C to A are provided at the base of the transistor Tr21.
All output currents from the output terminals a1, a2, ..., A15 of R15C are input. Then, by supplying a current equal to the input current signal to the capacitor C by the transistor Tr21 and the diode D20, average dimming in all areas AR1 to AR15 is performed. S _ST is a dimming start switch that is turned off when dimming is started, VR is a variable voltage source whose reference voltage is set to be changed according to film sensitivity, and COMP is a variable voltage for charging the capacitor C. It is a comparator that outputs a light emission stop signal STP by inverting the output when the reference voltage of the source VR is exceeded. After the exposure is started, the capacitor C is charged by the current from the transistor Tr21, and when the charging voltage exceeds the reference voltage, it is determined that the proper exposure is reached, and the light emission stop signal STP is output to stop the light emission of the flash. There is.

Next, the operation will be described. First, the control operation by the microcomputer (μC1) 1 will be described with reference to FIGS.
This will be described using 6. First, various flags will be described. Table 1 shows the contents of each flag and its set and reset states.

[0054]

[Table 1]

FIG. 18 shows an interrupt routine executed when the switch S ₁ , the recording start switch S _REC or the grip switch S _G is turned on. When an interrupt occurs, the microcomputer (μC1) 1 resets all flags and prohibits other interrupts to this flowchart (# 2, #
4). Subsequently, data indicating the operation states of various switches is input (# 6), and a subroutine "switch data input" is executed to perform control according to those switch operations.

FIG. 19 shows the "switch data input" subroutine. First, it is determined whether the transceiver TX is attached to the camera body 20 and the switch _SREM is turned on (# 30). If the switch S _REM is on, the switch data sent from the transmitter / receiver Rx is stored in the internal RAM of the microcomputer (μC1) 1 because it is remote control (# 32), and if the switch S _REM is off, All the switches on the camera body 20 side are monitored, the monitoring result is stored in the internal RAM (# 34), and the process returns. Any subsequent detection of the state of the switch is determined by the contents stored in this internal RAM.

Returning to FIG. 18, next, based on the switch data stored in the internal RAM, it is determined whether or not this interrupt is caused by turning on the switch S ₁ (#
8). If the switch S ₁ is on, the process proceeds to the "S ₁ ON" subroutine (# 10). If it is not on, it is judged whether or not the switch _SREM of the transceiver TX is turned on (# 12), and if it is on, the " _SREM " subroutine (# 14) is _executed to perform this control. If it is executed and the switch S _REM is not turned on, it is determined whether or not the moving image shooting switch S _REC is turned on (# 16). If the moving image shooting switch S _REC is turned on, the moving image subroutine "REC" is executed (# 18), and if it is not turned on, the "eyepiece" subroutine (# 20) is executed. Go to # 22. In # 22, the transistor Q1 is turned off in order to stop the power supply to the CCD / monitor / recording unit 10 and the like, and the interrupt to this flowchart is returned to the enabled state, and then stopped (# 24, # 26).

FIG. 20 shows the " _SREM " subroutine. First, subroutine "S1ON" to be described later is executed (# 40), whether the switch S _REM transceiver TX is on is determined (# 42). If it is turned on, a flag SREMF indicating this is set (# 44), and the process returns. If it is not turned on, the process returns as it is.

FIG. 21 shows the "eyepiece" subroutine. First, it is determined from the eyepiece flag SGRF whether or not eyepiece detection is performed (# 50). When the eyepiece detection is not performed, the count value N for timing is returned to "0", and the eyepiece flag SGRF indicating that this flowchart for eyepiece detection is executed is set (# 52, #). 54). Next, microcomputer (μC1)
1 turns on the light emitting element 291 of the eyepiece sensor 29 for 10 msec, and inputs data from the light receiving element 292 during that time (# 56, # 58). Then, it is determined whether or not there is light reception data (# 60). If there is no light reception data, the count value N is incremented, and then N =
It is determined whether or not it is K _N (# 62, # 64). N = K _N
If so, it is assumed that 2 seconds have passed, and the eyepiece flag SGRF
Is reset (# 66) and the process returns. On the other hand, N =
If not K _N , return to # 56.

If there is light reception data in # 60, it is determined that the photographer is looking into the finder 28, the transistor Q1 is turned on, and power is supplied to various circuits (# 68). Then, after waiting for 10 msec for the stabilization of the photometric and dimming circuit 9, the photometric data is captured (# 70, # 72). Then, the exposure calculation is performed from the photometric data in # 72 (# 74), and then A
F1 control is performed (# 76), then 100 mse
Only c is waited (# 78).

FIG. 22 shows the "exposure calculation" subroutine. In the exposure calculation, it is first determined from the result of the shooting mode setting whether the shooting mode is one of the silver salt still mode and the electronic still mode (# 110, # 11).
2) If both modes are not set, data that does not display aperture value (AV) / shutter speed (TV) is set (# 114), and the flow returns without performing exposure calculation.
On the other hand, if the shooting mode is either the silver salt still mode or the electronic still mode, the process proceeds to # 116. # 1
At 16, the film sensitivity reading device 6 reads the sensitivity SV of the loaded film. The exposure value EV is obtained by adding the photometric value BV to this (# 118), and then the exposure correction described below is performed (# 120). Furthermore, the exposure compensation amount ΔEV _AMB at that time for constant light and the exposure compensation amount Δ during preview
_Re-calculate the exposure value EV by adding EV _AMBPV (# 12
2). In addition, the exposure amount (ΔEV _FL ) + (ΔE) of the flash light amount that was exposure-corrected during the exposure correction and the preview.
V _FLPV ) is also corrected, and this variable voltage source VR is fed back to change the flash light amount, that is, as the correction of the dimming amount (# 124). The light emission amount itself may be adjusted by this correction amount.

Then, the exposure mode is determined (# 1
26), in the P mode, it is determined whether or not the flash is mounted (# 128), and if the flash is mounted, FL exposure calculation is performed based on the exposure value (# 13).
0) and AV / TV (aperture value / shutter speed) are required. If the flash is not attached, the exposure calculation I or II for constant light based on the constant light is performed based on the presence or absence of the recording mode determined based on the result of the shooting mode setting (# 132) (# 134). , # 136), AV
/ TV is required.

FIG. 23 shows an AV / TV program diagram. In this figure, the exposure calculation I for stationary light is represented by a diagram, and the exposure calculation II for stationary light is represented by a diagram. .
In FIG. 23, the diagram is such that the shutter speed is 1/60 between the minimum value and the maximum value of the diaphragm, and the shutter speed changes at both ends of the diaphragm according to the brightness. This diagram is adapted to the field (screen scanning) period of the television scan, and is used to control the aperture and shutter speed while shooting only a moving image or during shooting preparation. 1/250 when the maximum aperture is reached
The maximum aperture value is controlled up to the shutter speed of. This value 1/250 is set as the limit of the range that can be seen on a television as a moving image. The diagram is for still shooting when there is no video recording, and the aperture and shutter speed change at the same rate with respect to brightness. Further, a program diagram for high speed, a program diagram for prioritizing the aperture open effect for portrait, etc., or a program diagram for setting a large depth of field may be adopted. The line diagram is a program line diagram for still shooting during recording, which connects 1/250 and the maximum aperture value. This is intended to reduce aperture changes when moving from movie display mode to still shooting, to reduce shutter shake and image blur by increasing shutter speed, and to satisfy the continuity of movies. Therefore, the shutter speed is held down to 1/250.

If the exposure mode is the A mode, the S mode or the M mode, well-known exposure calculation is performed to obtain the AV / TV (# 138, # 140,
# 142), and returns.

FIG. 24 shows the "AF1" subroutine. The AF1 process automatically selects the main subject when the area detected by the line of sight is not set, and
The lens is driven according to the defocus amount of the area selected from the five areas. First,
The image data stored on the CCD / monitor / recording unit 10 side is input to the microcomputer (μC1) 1 in response to a read instruction from the microcomputer (μC1) 1 (# 160), and 15 image data are input based on the input image data. Each defocus amount of the area is calculated (# 162). Then, with the subject closest to the camera body 20 as the main subject,
The area is selected (# 164), the lens is driven based on the defocus amount (# 166), and the process returns.

Returning to FIG. 21, next, the preparation for photographing is performed at # 80. This "shooting preparation" subroutine is shown in FIG.
5 shows. Here, first, line-of-sight detection is performed in # 180, and an area for performing photometry and distance measurement processing is detected. Next, switch data for selecting various controls is input (# 182). Based on this switch data input, shooting mode setting, exposure mode setting, and AV / TV setting are performed (# 184 to # 188). Then, AF and AE (including exposure calculation) processing is performed based on the set area, switch data, and the set control value (# 190), and when these data are output (# 192), To return.

Here, the subroutine "line-of-sight detection" of # 180 will be described with reference to FIG. The visual axis detection, first, whether the switch S _REM image receiver TX are turned on is determined (# 200), if the switch S _REM is being turned on the remote control state, its liquid crystal display unit R8 Since the message is displayed and there is no need to look into the finder, the line-of-sight detection function is unnecessary and the process returns. vice versa,
If the switch S _REM is off, the image displayed on the monitor 47 is checked through the finder, so the process proceeds to step # 202 in order to control the line-of-sight detection.

In # 202, the light emitting section (infrared LED) in the visual axis detection circuit 2 is turned on for 10 msec, the emitted light is reflected by the eye of the photographer looking into the finder 28 and is received by the infrared area sensor. The received light data is taken in (# 204). The line-of-sight area seen by the photographer's eye is detected from the captured data, and the detected line-of-sight area is captured as an area ARN (N = 1 to 16) (# 206).

Next, it is judged whether the area ARN is the area AR16 (# 208). In the case of the area AR16, it is determined that the area cannot be detected because it is not within the detection area, and it is determined whether or not the timer flag TMF for measuring the time between them is set (# 21.
0) If not set, the timer flag TMF is set (# 212, # 214) after the timer T _AR is reset and started. In # 210, the timer flag T
When MF is set, the process directly proceeds to # 216 in order to continue the timer T _AR operation. In # 216, it is determined whether the timer T _AR has counted 5 seconds,
If 5 seconds have not passed, the process returns, and if 5 seconds have passed, the data for displaying the line-of-sight detection area frame 19 is set and the process returns (# 218). On the other hand, if the detected area is not the area AR16 in # 208, the timer flag TMF is reset, and then the data for displaying the line-of-sight detection area frame 19 is reset.

Subsequently, at # 224, it is determined whether or not the switch S _SDI for setting or resetting the area ARN in which the line of sight is detected has been turned on. If it has not been turned from off to on, it returns as it is. If it is turned from off to on, it is subsequently determined whether or not the area reset flag RSTF is set (# 226). Area reset flag RS
When TF is set, this flag is reset and then the current detection area ARN is set to the set area LARN.
And the area flag ARF indicating the area designation is set (# 228, # 232, # 23).
4) Then return.

On the other hand, if the area reset flag RSTF is not set at # 226, the set area LA is set.
It is determined whether the RN and the current detection area ARN are equal (# 230). If both areas are equal, switch S
It is determined that _SDI has been operated to cancel the designated area LARN, and the area reset flag RST
F is set, then the data for display of the line-of-sight detection area frame 19 displayed when the power is turned on is set, and the line-of-sight area is reset and the area flag AR is set.
After F is reset (# 236 to # 240), the process returns. If the setting area LARN is not equal to the current detection area ARN in # 230, it is determined that the switch S _SDI has been operated for area setting, the processing of # 232 and # 234 is executed, and the process returns.

Subsequently, the "shooting mode setting" subroutine of # 184 will be described with reference to FIG. First, it is determined whether or not the flag MDTF indicating that the shooting mode is being set is set (# 250), and if not set, it is determined whether or not the shooting mode change switch S _MDT is turned from off to on (# 252). If the mode is turned from off to on, it is determined that the setting mode has been entered, the flag MDTF is set (# 254), and the process returns. On the other hand, if the mode is not changed from off to on, the process returns. # 250
Then, if the flag MDTF is set, the front dial 3
3 or the operation of the rear dial 34, the shooting mode is 1 to 7
Changes cyclically (# 256).

Table 2 shows combinations of the photographing modes 1 to 7 and operating states of moving image photographing, electronic still and silver salt still.

[0074]

[Table 2]

When the photographing mode change switch S _MDT is turned on from off (# 258), the flag MDTF is reset (# 26) because the setting mode is exited.
0), return, otherwise return as it is.

The "exposure mode setting" subroutine will be described with reference to FIG. 28, and the "AV / TV setting" subroutine will be described with reference to FIG.

In the "exposure mode setting" subroutine, it is first judged whether or not the flag MDF indicating that the exposure mode is being set is set (# 270). If not set, then the exposure mode change switch is set. S
_It is determined whether _MD is turned from off to on (# 2
72). If the exposure mode change switch S _MD is turned from off to on, it is determined that the setting mode is entered, and the flag MDF is set. On the other hand, if it is not from off to on, the process directly returns. If the flag MDF is set in # 270, the exposure modes A, M, S and P are set in accordance with the operation of the front dial 33 and the rear dial 34.
Are cyclically changed in this order (# 276). Next, it is determined whether or not the exposure mode change switch S _MD has been changed from off to on (# 278), and if it is changed from off to on, it is determined that an operation has been performed to exit this setting mode. Reset the flag MDF ((
280) On the contrary, if the operation from off to on has not been performed, the process directly returns.

In the "AV / TV setting" subroutine, first, the flag MDF indicating the exposure mode setting, the flag ECRF indicating the exposure correction by the constant light, the flag ECR _FL F indicating the exposure correction by the flash light and the white balance correction are set. It is determined whether the respective flags WBF are set (# 290 to # 296). If any of them is set, it is determined that the mode is set, and the process directly returns. If neither is set, the exposure mode at that time is determined (# 29
8) The following processing is executed. If the exposure mode is the P mode, so-called P shift processing is performed in which the shutter speed TV increases or decreases in the opposite direction in response to the increase or decrease in the aperture value AV (# 300). If the exposure mode is the A mode, the aperture value AV is changed (# 302). If the exposure mode is the S mode, the shutter speed TV is changed (# 304). If the exposure mode is the M mode, the aperture value AV is changed by operating the front dial 33, and the shutter speed TV is changed by operating the rear dial 34 (# 3).
06, # 308). Then, after this processing, the process returns.

Next, the "AF / AE" subroutine will be described with reference to FIG. In this subroutine, first, photometric data is input (# 320), and then G in the R, G, B image data from the microcomputer (μC2) 100.
(Green) data is input (# 322). Next, it is determined whether or not the switch _SREM of the transceiver TX is turned on (# 324). If it is turned on, the line-of-sight detection is not necessary as described above, and therefore the temporary focus detection of AF1 is performed and the photometry is performed. The value BV is fetched and the exposure calculation is executed (# 330 to # 334). If the switch S _REM is not turned on, the switch S _SDI (line-of-sight operation member 3
Based on the operation 0), it is determined whether or not the area flag ARF is set (# 326).

If the area flag ARF is not set, it is next determined whether or not the area reset flag RSTF is set (# 328). When the area reset flag RSTF is set, AF,
Since it is not known to which area ARN the AE processing should be performed, A is set until the area AR is set next time.
In order to lock the F / AE, # 330 to # 334 are skipped, the focus flag AFEF indicating the focus is reset ((#
336), and return. In # 328, when the area reset flag RSTF is not set, it means that the area AR has never been set since the power was turned on.
In this case, AF and AE are always applied to various subjects.
It is better not to lock the AF / AE so that the processing can be performed, and the temporary focus detection of the AF1 described above is repeatedly performed (continuous AF), and the photometric value BV is taken in each time and the exposure calculation is further performed. After that, the focus flag AFEF indicating the focus is reset (# 330 to # 33).
4) Return.

On the other hand, if the area flag ARF is set by the switch S _SDI (line-of-sight operating member 30) in # 326, it is determined whether or not the switch S ₁ is turned on (# 338). If the switch S ₁ is not turned on, A
The flag AFEF indicating the focus is reset so as to make the F mode continuous (# 340). Switch S
_{If 1} is on, the process directly proceeds to # 342.

At # 342, it is judged whether or not the focus flag AFEF indicating that the focus is once set is set. Shot AF) and return. If not set, focus detection is performed, and it is determined whether or not focus is achieved based on the result (#
344, # 346). If out of focus, the taking lens 211 is driven based on the result of focus detection (# 348),
The process returns to # 344 again. Then, if it is determined to be in focus at # 346, a focus flag AFEF indicating that focus has been set is set, and then photometry is performed (# 350, # 35).
2) Return.

The "focus detection" subroutine will be described with reference to FIG. 31, and the "photometry" subroutine will be described with reference to FIG.

In focus detection, the defocus amount DF _N in the area AF corresponding to the set area ARN is calculated and the process returns (# 360).

Next, "photometry" will be described. Table 3 is a table showing the relationship between the detected line-of-sight area and the photometric data.

[0086]

[Table 3]

In photometry, first, the subject distance DV is calculated based on the lens extension amount, the focal length f is further taken in, and the image magnification β is calculated from the subject distance DV and the focal length f (# 370). ~ # 374). Then, it is determined whether or not the obtained image magnification β is equal to or larger than a predetermined value K _B (# 376). If the image magnification β is equal to or _larger than the predetermined value K _B , the photometric data of the AR area is output from the CCD / monitor / recording unit 10 based on “Photometry A” in Table 3 above, and the average value thereof is calculated ( # 378, # 382). vice versa,
If the image magnification β is less than the predetermined value K _B , “Photometry B” in Table 3
Based on the above, the photometric data for the AR area is output in the same manner as described above, and the exposure calculation is executed from this photometric data (# 380, # 382). In the above, when the image magnification β is small, the photometric data of a plurality of areas are averaged so that the entire landscape or the like can be photographed appropriately.

Returning to FIG. 21, after the photographing preparation processing is executed, it is judged whether or not the switch S ₁ is turned on (# 82). If switch S ₁ is on,
The "S ₁ ON" subroutine is executed (# 84), and it is further determined whether or not the grip switch S _G is on (#
86), if on, proceed to # 80. At this time, if the grip switch S _G is off, proceed to # 66 (#
88), reset the flag SGRF and exit the eyepiece routine. On the other hand, if the switch S ₁ is not turned on in # 82, it is determined whether or not the switch S _REC for starting the recording of the moving image is turned on (# 90).
_{If REC} is on, the “RE
The "C" subroutine is executed (# 92). On the other hand, if the switch _SREC is not on, the "reproduction" subroutine is executed (# 94).

Here, the above-mentioned "reproduction" subroutine will be described with reference to FIG. First, it is determined whether the shooting mode is the silver salt still mode or the electronic still mode. If neither shooting mode is selected (NO in both # 400 and # 402), the preview (pre-) and post-check control is prohibited. And return. If the shooting mode is either the silver salt still image or the electronic still image, the process proceeds to step # 404 to control the preview and the subsequent confirmation. In # 404, the state of the flag RECF is determined, the flag RECF is set,
That is, if recording is in progress, the process returns to prohibit the preview operation and the subsequent confirmation display operation by the monitor 47. If recording is not in progress, it is determined whether or not the switch _SPV is turned on from off (# 406). If the switch _SPV is turned on from off, the "preview" subroutine is executed (# 408), and the process returns. If not, return as it is.

When the "playback" subroutine ends,
Return to 21, grip switch S _GIs turned on
It is determined whether or not (# 86). Grip switch S
_GIf is off, proceed from # 88 to # 66 and set the flag.
Reset SGRF and exit the eyepiece routine. one
Person, grip switch S_GIf is on, proceed to # 80.
Mu.

Next, the "S ₁ ON" subroutine will be described with reference to FIGS. 34 and 35. When the switch S ₁ is turned on, it is first determined whether the shooting mode is the silver salt still mode or the electronic still mode (# 42).
0, # 422), if none of the shooting modes, warning data is set (# 424), and this data is output to display a warning (# 426). Then, it waits for the vertical synchronizing signal V _sync (# 428), and when this signal is input, it is determined whether or not the switch S ₁ is off (# 430). If the switch S ₁ is off, the process returns, and if it is on, the process proceeds to # 426.

On the other hand, if the photographing mode is the silver salt still mode or the electronic still mode, the eyepiece flag SG indicating the eyepiece detection.
It is determined whether RF is set (# 43).
2). If the eyepiece is detected here, the photographing preparation operation is performed (# 434), and the process proceeds to # 436. In # 436, it is determined whether or not the switch S ₂ is turned on. If the switch S ₂ is not on, it is determined whether or not the moving image shooting mode is selected in the shooting mode (# 4
38), if it is the video shooting mode, the switch S for recording
Determine if _REC went from off to on (#
440). If the switch S _REC is switched from OFF to ON, it is determined that the operation for moving image shooting is performed, and it is determined whether or not the flag RECF indicating that the moving image shooting mode is set is set (# 442). If the flag RECF is not set, the switch S is used to start recording.
_The flag RECF is set as if the _REC was operated (# 444), and the data for instructing the start of recording is CCD /
Output to the monitor / storage unit 10 (# 446), # 4
Move to 34. On the other hand, when the flag RECF is set, the switch S is used to stop the recording during recording.
_{As the REC} is operated, the flag RECF is reset (# 448), and the data for instructing the recording stop is CCD /
Output to the monitor / storage unit 10 (# 450), # 4
Move to 34.

On the other hand, if it is not in the moving image photographing mode in # 438, or if the switch S _REC is not turned from ON to OFF in # 440, the process proceeds to # 452. In # 452, the "playback" subroutine is executed, and then it is determined from the state of the flag RECF whether or not recording is in progress (#
454). If recording is in progress, the process proceeds to # 434 and the recording operation is continued. If recording is not in progress, it is determined whether or not the switch S ₁ is turned off (# 456), and if not turned off, the timer _TH is reset and started (# 458) and the process proceeds to # 434. On the other hand, if the switch S ₁ is off, it is determined whether or not the timer T _H has counted for 5 seconds (# 460), and until the time elapses, #
Proceed to 434, and if the time has passed, return. In addition, # 4
In 32, if the eyepiece flag SGRF is not set, this flag is set (# 462), and # 68 is set.
Proceed to (Fig. 21).

If the switch S ₂ is turned on in # 436, the process proceeds to # 464 to execute the photographing operation.

Next, this "photographing" subroutine will be described with reference to FIG. First, it is determined from the state of the flag RECF whether or not recording is in progress (# 480),
If recording is in progress, the lens drive is stopped during shooting in the shooting mode of silver salt still and electronic still (# 482),
Proceed to # 484, and if recording is not in progress, continue with # 484.
Proceed to. In # 484, the control necessary for shooting (shooting I) is performed, the winding process is further performed (# 486), and then the flag AFEF indicating the focus is reset (# 4).
88) and return.

Now, the subroutine of "imaging I" will be described with reference to FIG. The data of switch S ₂ ON is output (data output) to the CCD / monitor / recording unit 10 (# 500), while waiting for the exposure OK signal to be input from the CCD / monitor / recording unit 10 (# 5).
02). When the exposure OK signal is input, the input of the vertical synchronizing signal V _sync is waited (# 504),
When this is input, aperture control according to the required aperture value is performed (# 506). Next, an exposure start signal is output to the CCD / monitor / storage unit 10, where the camera waits for 10 msec until the diaphragm stabilizes (# 508, # 510). Subsequently, it is determined whether or not the silver salt still image capturing mode is set (# 512). If the silver salt still image capturing mode is set, then exposure control, that is, shutter control (focal plane shutter 46 for silver salt) is performed.
Is performed (# 514). When not in the silver salt still photography mode, shutter control is not necessary and the operation is waited so that the aperture charging operation and the like are not performed during the exposure operation of the CCD 43 (# 516).

Here, the "winding" subroutine after the exposure is completed will be described with reference to FIG. First, it is determined whether or not it is the silver salt still photography mode (# 530), and if it is the silver salt still photography mode, the film 45 is wound up by one frame and the shutter charge is performed (# 532).
Return, otherwise return as it is because winding is not necessary.

Then, returning to FIG. 34, it is determined whether or not continuous shooting is performed (# 466). If continuous shooting is performed, # 434 is executed.
Proceed to. Thus, by obtaining new data for integration and AF and AE processing in the CCD 43 during continuous shooting,
It is possible to show the moving image to the photographer. On the other hand, # 4
66, if the continuous shooting, wait until the switch S ₁ is turned off (# 468), the switch S ₁ is turned off, the process proceeds to # 434.

Next, the "preview" subroutine is
This will be described with reference to FIG. First, dimming start switch S _ST
There is turned on, the flag 2ndF showing a second shooting is reset, data indicating the state of the switch S _PV is CCD
/ Output to the monitor circuit 10 (data output) (# 5
40- # 544). Next, the microcomputer (μC1) 1
Wait for the exposure OK signal to be input from the CD / monitor / recording unit 10 (# 546).

Then, when the exposure OK signal is input, it waits for the vertical synchronizing signal V _{sync to} be input (# 548),
When this signal V _sync is input, the aperture is controlled by the control aperture value, and the exposure start signal is output to the CCD / monitor / recording unit 10 (# 550, # 552).

Next, the stabilization of the aperture is waited (# 55
4), a signal for turning off the dimming start switch S _ST is output (# 556). Then, after waiting for a time corresponding to the exposure time (# 558), it is determined whether or not the flag 2ndF is set (# 560). Flag 2nd
If F is not set, it is next determined whether or not flash photography is performed (# 562). If flash photography, and sets the flag 2ndF to perform the second shooting (# 564), the switch S _PV instructing preview is turned on from off along with this (# 566). The data indicating the change of the switch S _PV from OFF to ON is CC
It is output to the D / monitor / storage unit 10 side (# 544),
It is used to control the monitor 47. On the other hand, if the flag 2ndF is set in # 560 or if the flash photography is not performed (NO in # 562), the focus flag AFEF is reset (# 568), and then the exposure correction for the captured image in the preview is performed. Exposure correction (# 570), color correction (# 572), and data output (# 5
74) is performed and the process proceeds to # 576. This exposure correction and color correction make it possible to know in advance the corrected image state when the image is actually taken.

The "exposure correction" subroutine will be described below with reference to FIG. First, it is determined whether or not the flag ECRF indicating the exposure compensation mode is set (# 600). If not, whether the exposure compensation switch S _{(+/-) AMB} is turned from off to on. If it is determined (# 602) that it has not changed from off to on, the process proceeds to # 612. On the other hand, if the exposure compensation switch S _{(+/-) AMB} is turned on from off, it is determined that the exposure compensation mode is entered, and the flag ECRF is set.
Proceed to 600. When the flag ECRF is set in # 600, the exposure correction amount ΔEV _AMB in the constant light is set according to the operation amount of the front dial 33 and the rear dial 34,
Next, it is determined whether or not the exposure compensation switch S _{(+/-) AMB} is turned from off to on (# 608). If the exposure compensation switch S _{(+/-) AMB} has not changed from off to on, it returns as it is, and if it changed from off to on, the flag ECRF is reset to exit this mode (# 610). , Return.

In # 612, it is judged whether or not the flag ECR _FL F indicating the exposure correction of the flash light amount is set. If not set, the process proceeds to # 614.
On the other hand, if it is set, the process proceeds to # 618. Subsequent # 6
The procedure from 14 to # 622 is the same as the procedure from # 602 to # 610, and the description thereof will be omitted. However, the exposure correction amount ΔEV _FL shown in # 618 is for flash light.

Next, the control when the color correction operation is performed will be described. This color correction adds a correction depending on the type of film loaded, as described below.

There are various types of light sources for taking photographs. 41 (a) to 41 (d) show a part of the spectral characteristics thereof, and natural daylight is not spectrally biased, but tungsten light has a characteristic biased in the red region. To be However, human beings are able to accurately recognize the color of an object illuminated by tungsten light because their vision is adaptive to color. On the other hand, the color film has three photosensitive layers each having a sensitivity of one of the three colors of B (blue), G (green) and R (red). Produces all colors in ratio. The spectral sensitivities of the three layers to light can be roughly classified into two types, one is a daylight type that is balanced so that normal colors can be reproduced when shooting with natural light or strobe light during the day. Yes, the other one is a tungsten type that is balanced so that a normal color can be reproduced when the image is taken with tungsten light. 42A and 42B show examples of both types of spectral sensitivity. As can be seen from the figure, since the daylight type film has a higher sensitivity to the R light than the tungsten type film, a reddish photograph is obtained when the tungsten light having a large R component is taken. This is because the color film is not adaptable to human-like colors. It is necessary to correct the difference in appearance due to such a film on the monitor 47 so that the finish condition can be confirmed in advance.

Next, the "color correction" subroutine is shown in FIG.
3 will be used for the explanation. First, the flag WB for color correction
It is determined whether or not F is set (# 63
0), if not set, it is judged whether or not the color correction switch _SWB is turned on from off (# 63).
2). If the color correction change switch _SWB is turned from OFF to ON, the flag WBF is set to set the color correction mode (# 634) and the process returns, while the color correction switch _SWB is turned OFF. If it is not turned on from, it returns as it is. When the flag WBF is set in # 630, it is determined that the color correction mode is set, and the blue and red correction amounts ΔB _C and ΔR _C are set according to the operation of the front dial 33 and the rear dial 34 (# 6).
36, # 638). Then, the color correction switch S _WB is discriminated whether turned on from off (# 640), if the color correction switch S _WB is turned from off to on,
The flag WBF is reset to exit the color correction mode (# 642), and the process returns, and otherwise the process returns.

Returning to FIG. 39, the switch S _{PV is} pressed at # 576.
If is not turned from off to on, proceed to # 570. Color correction and exposure correction are performed while the still image is displayed (# 570, # 572). On the other hand, when the switch _SPV is turned on from OFF in # 576, the switch data is output (data output) to the CCD / monitor / storage unit 10 (# 578), and then the power holding timer _TH is reset and started. (# 580). Subsequently, the red and blue correction amounts ΔR _C and ΔB _C are respectively stored as ΔR _CR and ΔB _CR (# 582 and # 584), and the flag WBF and the correction amounts ΔR _C and ΔB _C are reset (# 586). , # 58
8) Return. This is because the color correction may be reset in the actual photographing, so that the photographer can adopt either one according to his / her preference at the time of previewing.

Here, the #REC "REC" subroutine will be described with reference to FIGS. 44 and 45. First, R
In the EC mode, that is, whether or not recording (video) is being discriminated from the state of the flag RECF (# 650). If recording is not in progress, warning data is set (# 690), and this data is output to display a warning. (# 692). Then, it waits for the vertical synchronizing signal V _sync (# 694), and when this signal is input, it is determined whether or not the switch S _REC is off (# 696). If the switch S _REC is off,
If the process returns and is on, the process proceeds to # 692.

On the other hand, if recording is being performed at # 650, it is determined whether or not the eyepiece flag SGRF is set (# 652). If not set, this flag is set (# 654) and # 68. Proceed to. If set, the timer is reset and started (# 656),
Next, the exposure mode is set to the P mode (# 56
8). Subsequently, an operation for preparing for shooting is performed (# 66
0), it is determined whether the shooting mode is the silver salt still mode or the electronic still mode (# 662, # 664). If any of the shooting modes is selected, it is next determined whether or not the switch S ₂ is on (# 666). If it is on, shooting is performed in the set silver salt still shooting mode or electronic still shooting mode. (# 668), the process proceeds to # 660. If neither the silver salt still shooting mode nor the electronic still shooting mode is selected, or if the switch S ₂ is not on, it is determined whether or not the recording start switch S _REC is turned from off to on (# 670), and then from off to on. If so, it is determined from the state of the flag RECF whether or not recording is in progress (# 672). If recording is in progress, the flag RECF is reset (# 678), a recording stop signal is output (# 680), the timer is reset and started (# 684), and the routine proceeds to # 660. On the other hand, if recording is not in progress, the flag RECF is set (# 67
4), the recording start signal is output (# 676), and the timer is reset and started (# 684).
Proceed to.

If it is determined in step # 670 that the recording start switch S _REC is not turned on from off, it is determined from the state of the flag RECF whether or not recording is in progress (# 682). Still image preview (prior)
After the confirmation display is displayed (# 686), it is determined whether 5 minutes have passed without recording and no operation is performed (# 688), and if 5 minutes have passed, return To do. Until 5 minutes have passed, proceed to # 660. If recording is being performed in # 682, the timer is reset and started (# 684), and the flow proceeds to # 660.

Next, at the time of remote control, control of a data interrupt when it is sent from the microcomputer (μC3) 140 of the transceiver TX is performed.

This "data interrupt" subroutine is shown in FIG.
This will be described using 6. In this subroutine, when a signal indicating a data interrupt is input from the microcomputer (μC3) 140, subsequently, the microcomputer (μC3) 140 is sent from the transmitter / receiver RX during remote control, or data is being sent. Is input to the microcomputer (μC1) 1 (# 710). Next, it is determined whether or not the flag SREMF indicating the remote control mode is set (# 712). If the flag SREMF is not set, the remote control switch SREM is not turned on, and the process returns because it is not in the remote control mode. On the other hand, when the flag SREMF is set, it is returned to the reset state (# 714),
In step # 40 (FIG. 20), remote control is performed.

Next, FIGS. 47 to 57 show the sequence on the CCD / monitor / recording unit 10 side, which will be described with reference to the flowchart executed by the microcomputer (μC2) 100.

FIG. 47 is a flow chart showing an interruption due to power-on or the like and an interruption due to data input from the microcomputer (μC1) 1. That is, the power source is a microcomputer (μC
2) When supplied to 100, first, initial reset is performed for all flags, registers, etc. (S2). In this state, the display is performed by outputting the data from the frame memory 121, but since there is no moving image in the frame memory 121 when the power is turned on, no image is displayed. The CCD 43 is exposed, and an image is displayed after a time of several frames has passed. next,
The shutter speed TV of the CCD 43 is set to 1/60, a timing signal is generated from the timing signal generation circuit 101 according to the setting data, and the CCD 43 is controlled (S4). An interrupt due to data input from the microcomputer (μC1) 1 takes place at S6, where switch S
_It is determined whether ₂ is turned on, and if it is turned on, the "exposure control I" subroutine is executed (S
8). On the other hand, if the switch S ₂ is not turned on, it is determined whether the switch S _PV is turned from off to on (S
10) If the switch _SPV is switched from OFF to ON, PV control is performed (S12). If the switch _SPV does not change from OFF to ON, the flag PVF indicating the preview mode is displayed.
It is determined whether or not is set (S14).
If the flag PVF is set, color correction (manual correction, correction by film type) and exposure correction (by constant light or flash light) are performed (S1).
6, S18), if the flag PVF is not set, it is determined whether or not the switch S _DPI for displaying a still image has been turned from off to on (S20). If the switch S _DPI is turned on from off, the display control I for displaying a still image is executed (S22), and the switch S
_{If the DPI} does not change from off to on, it is determined whether or not the flag DPIF indicating that this mode is set is set (S24). If the flag DPIF is set, the display control II for changing the display is executed (S26), and if the flag DPIF is not set, the process directly proceeds to S28.

In S28, color correction is carried out, and then the above-mentioned marks and characters showing the photographing mode are displayed (S30). Then, the display data from the microcomputer (μC1) 1 for displaying the shutter speed and the photographing mode is output to the microcomputer (μC21) 120 which performs image processing, and further based on the input image data (R, G, B). Then, the aperture value in the moving image is calculated, and the exposure control is performed based on the calculated aperture value (S32). In addition, WB control is performed by the WB control data obtained based on the input image data (R, G, B) (S32, S34), and S6
Proceed to.

Next, the "exposure control I" subroutine will be described with reference to FIG. First, the variables N _E and N _T are reset (S40, S42). The variable N _E indicates the number of exposure operations for each 1/60 during one shooting, while the variable N _T indicates the required number of exposure operations for each 1/60 during one shooting.

[0117] Then, the shutter speed TV from the microcomputer (.mu.C1) 1 is converted into a real time T _CCD (S4
4). Here, the shutter speed TV is 6 or more (1 /
It is determined whether the shutter speed is 60 or less) (S46). If the value is 6 or more, the process directly proceeds to S56. On the other hand, if the shutter speed TV is less than 6,
The calculation of N _T = T _CCD / (1/60) is performed on the variable N _T , and N _T = N _AGC is set (S48, S50), and the exposure time is set to 1/60 which matches the field time (S52). ),
A flag MEXPF indicating that the exposure operation is repeated N _T times at 1/60 is set (S54).

In the present embodiment, moving image / still photography (hereinafter, simply referred to as still photography includes both silver salt still photography and electronic still photography) is possible. One field is captured and recorded for each / 60. On the other hand, in still photography, particularly when the exposure mode is the P mode and the A mode, the exposure time is arbitrarily set according to the brightness. Has been decided. Further, when the exposure time is 1/60 or more, in moving image shooting, the image pickup is repeated every 1/60, and the _AGC 109 adjusts the gain based on the N _AGC so that the exposure is longer than 1/60. Deal with time, while in still photography, as described below,
Exposure times longer than 1/60 are addressed by summing multiple images taken with every / 60 exposure.

At S54, the exposure OK signal is output to the microcomputer (μC1) 1 (S56). Microcomputer (μC1)
1 starts exposure control based on the photographing method set as described above. Next, wait for the exposure start signal from the microcomputer (μC1) 1 to be input (S58),
When this signal is input, a flag EXPF indicating that exposure is being performed is set (S60). continue,
After the exposure is completed and the flag EXPF is reset (S62), the process returns.

The detection range in exposure, WB, and shake detection described later in the moving image shooting mode is the entire range of the line-of-sight detection display frame 19 in FIG. 12, which is the range of line-of-sight detection in the still shooting mode. different. The reason for this is the exposure, W
When the brightness and color change due to the change of the detection range in B, the exposure and color of the image change frequently following this, so the screen may be difficult to see in the moving image and shake This is because if the detection range is narrow, it is difficult to distinguish the shake of the camera itself from the movement (moving body) of the subject.

FIG. 49 shows the CCD / monitor / recording unit 10.
Below is a timing chart to explain the operation of
The outline of the operation will be described with reference to this figure.

First, the case of stationary light photography will be described. In the uppermost "operation" in the figure, when the release switch S ₂ is turned on, data indicating shooting is output from the microcomputer (μC1) 1 to the microcomputer (μC2) 100. The microcomputer (μC1) 1 performs a predetermined control for photographing, while the microcomputer (μC2) 100 receives the above data and performs a predetermined control, and then sends an “exposure OK” signal to the microcomputer (μC1). Return to 1. When the microcomputer (μC1) 1 receives the exposure OK signal, it waits for the vertical synchronization signal V _sync of the next cycle to be input, sends an “exposure start” signal to the microcomputer (μC2) 100, and controls the aperture. "Aperture control", and thereafter, the shutter 46 is driven "shutter exposure control". The microcomputer (μC2) 100 performs “CCD exposure control” that controls the exposure of the CCD 43 at the cycle of the vertical synchronizing signal V _sync of the next cycle.

Now, let us say that the image picked up at the first time in the exposure control for each vertical synchronization signal V _sync is A1, and the second and subsequent times are A2, A3, ..., An. The signal of the first (first cycle) image A1 is the microcomputer (μC2) 100 after the exposure is completed.
The microcomputer (μC21) 120 performs predetermined image processing during the second period based on the signal from and is stored in the frame memories 121 and 122. The exposure control for the next image A2 is performed within the second period. here,
Assuming that the exposure time for proper exposure is 1/60 or more, the microcomputer (μC2) 100 outputs a control signal to the microcomputer (μC21) 120 in the third cycle, and the “adder O
N ”, the adder circuit 124 is turned on, the image A2 is added to the image A1 stored in the frame memory 121, and the image is stored in the frame memory 122. After that, this process is repeated until the exposure control ends (Nth cycle), the image captured by the CCD 43 is stored in the frame memory 121, and the frame memory 122 is sequentially added as described above. The image of ΣAi is stored. At this time,
The images stored in the frame memory 121 are sequentially displayed on the monitor 47 in the next cycle to obtain a moving image. Although the moving image at this time is displayed with insufficient exposure, when the switch S _DPI is operated, the microcomputer (μC2) 100 to the microcomputer (μC21) 12
A signal for instructing “display switching” is output to 0, whereby the ΣAi-processed still image is displayed in an appropriate exposure state. On the other hand, when the exposure time is 1/60 or less, the image Ai is stored in the frame memory 122 with a delay of one cycle. The image Bi in the next exposure control is similarly processed.

Next, memory control during flash photography will be described. The exposure time at this time is 1/6
It is 0 or less. The captured image A1 is stored in the frame memory 12
Stored in 2. Image O _N stored immediately before the frame memory 121 at this time are preserved, the image is displayed. This is to prevent noise from appearing to be mixed when only the image captured by flash photography for one cycle is included in the stationary light photography.

Next, referring to FIGS. 50 and 51, "V _sync
The “interrupt” will be described. When the vertical synchronizing signal V _sync is input, it is determined whether or not the flag EXENF indicating the end of exposure is set (S80). If not set, flag 1stF indicating the last exposure during exposure
Is set (S96).
If not set, a flag EXPF indicating that exposure is in progress
Is set (S10).
2). When the flag EXPF is set, the data of the exposure time T _CCD is output to the timing signal generation circuit 101, the control signal is output to the AGC 105, and its gain is set to 1 (not amplified) (S112, S11
4). WB is then uncontrolled and flag 1s
tF is set (S116, S118). continue,
The flag MEX indicates whether the control requires multiple exposure operations.
It is determined from the state of PF (S120), and if a plurality of exposure operations are required, it is determined whether or not the variable N _T is 1 (S122). If the variable N _T is 1, it means the last exposure, and the process proceeds to S128. On the other hand, if the variable N _T is not 1, the variable N _T is decremented by 1 (S124),
At this time, since it is not at least the last exposure, the flag 1stF is reset (S126) and the process proceeds to S128.

In S128, the variable N _E is incremented by 1, the gain of the AGC circuit 105 is set to N _AGC in order to optimize the exposure (S130), and then it is determined whether or not the variable N _E is 3. (S132). Variable N _E
Is 3, the data for turning on the adder circuit 124 is set (S134), and then the frame memory 12
The data instructing the operation of adding the image stored in No. 2 and the latest image input from the microcomputer (μC21) 120 and storing in the frame memory 122 is set (S136). If the variable N _E is not 3, S as it is
Proceed to 138. In S138, the microcomputer (μC2) 10
The data set to 0 is the microcomputer (μC21) 12
0 (S138), then the microcomputer (μC1)
Based on the data from No. 1, it is determined whether the FL shooting in the preview shooting or the FL shooting in the electronic still shooting is performed (S140, S142). Which FL
If it is not photographing, shake detection is performed based on the G (green) component data input for each field, and shake correction control is performed based on this result (S148), and the process returns. On the other hand, in the case of FL shooting by preview shooting or electronic still shooting, measurement is performed for a predetermined time, for example, 8 msec, a flash light emission signal is output (S144, S146), and the process proceeds to S148.

If the exposure in the still photography mode is not being performed in S102, a signal for setting the exposure time to 1/60 is output to the timing signal generation circuit 101 (S104), and AG
A signal for setting the C circuit 105 to automatic and the AGC circuit 109 to gain 1 is output (S106, S1).
08), then the WB control signal is output, and S13
Go to 2.

When the last exposure operation is completed in S96 and the next field is reached (flag 1stF =
1) The memory control is performed, the flag EXENF indicating the end of the exposure control is set, and the process proceeds to S104.

Now, the "memory control" subroutine will be described with reference to FIG. First, the microcomputer (μC
1) It is determined based on the input data from 1 whether it is FL shooting (S160), and if it is FL shooting, updating of the stored contents of the frame memory 111 and the frame memory 121 used when recording a moving image is prohibited. , A control signal for prohibiting the input of image data is output (S162, S
164). In this way, by prohibiting the data update and storing and holding the image of the previous screen (corresponding to the image O _N shown in FIG. 50), only one field is included in the images of continuous continuous light photography. It is possible to prevent the noise-like display due to the inclusion of the FL captured image.

Next, data for passing the image data as it is is set in the adder circuit 124 (S16).
6) It is determined whether or not it is FL shooting in the preview (S168). If the FL shooting is in the preview, the data for storing the image data is set in the frame memory 123 (S170). On the other hand, if the FL shooting is not in the preview, the image data is stored in the frame memory 122. Data is set (S17)
2). On the other hand, if it is not the FL shooting in S160, the process proceeds to S174 without performing such processing.

In S174, it is determined whether or not continuous shooting is performed,
If it is continuous shooting, data for instructing storage in the internal memory 129 is set for the time being (S176), and S178.
On the other hand, if it is not continuous shooting, the process directly proceeds to S178, and it is determined whether or not the electronic still shooting mode is set. If it is the electronic still photography mode, the data for instructing the data storage in the IC card 51 is set (S180) and the process returns. If not, the process returns as it is.

Returning to FIG. 50, the flag EXEN is set in S80.
If F is set, it is assumed that the exposure control has finished.
This flag EXENF is reset (S82), then data for turning off the adder circuit 124 is set (S84), and the input image data is stored as it is in the frame memory 121. Next, the flag 1stF, the flag EXPF, and the flag MEXPF are reset (S86 to S90) to enable continuous recording of the moving image, and further, the frame memory 12
Data for instructing restart of data input to 1 is set (S92, S94). These S92, S94
By the processing of (1), the prohibition state of each data input at the time of FL photographing is released.

Next, "PV control", "exposure correction" in preview mode and "color correction" in preview mode shown in FIG. 47 will be described with reference to FIGS. In FIG. 53, first, it is determined whether or not it is the second continuous shooting in the preview mode, that is, whether or not FL flash shooting is performed (S1).
90). If it is not the second time, it is judged from the state of the flag PVF whether it is in preview (S192). If it is in preview, this flag PVF is reset (S1).
98), exits the preview mode and returns. On the other hand, if the preview is not being performed, the flag PVF is set so that the preview is being performed (S194), the exposure control is performed (S196), and the process returns. When the second continuous shooting in the preview mode is performed in S190, the exposure control is performed (S196) and the process returns.

In FIG. 54, first, the microcomputer (μC1) 1
It is determined whether or not the correction amount of the FL light from is changed with respect to the previous input value, and if it is changed, the change amount ΔEV _FLPV is obtained and set (S210, S21).
2) Then, it is determined whether or not the correction amount in the constant light has changed with respect to the previous input value, and if it has changed, the change amount ΔEV _AMBPV is obtained and set (S2
14, S216), and returns. In addition, the correction with FL light is {(memory 122)-(memory 121)} × (Δ
EV _FLPV ) + (memory 123), and the obtained data is stored in the memory 122. In addition, the correction with constant light is (memory 122) × (ΔEV _AMBPV ) + {(memory 123)
-(Memory 122)}, and outputs the data for storing the obtained data in the memory 122.

In FIG. 55, first, the correction data ΔB, ΔR
Is set to a value 0, and the correction amount Δ to be corrected based on the color correction data ΔB _C , ΔB ₂ input from the camera body 20 side.
R _C and ΔR ₂ are obtained (S220). Next, it is determined whether the film type is daylight, tungsten, or black and white (S222), and if the loaded film is the tungsten type, the color correction amount Δ corresponding to this is determined.
Let B ₁ and ΔR ₁ be ΔB _t and ΔR _t (S224, S22
6) If it is a daylight type, ΔB _d and ΔR _d are set (S234, S236). Then, the overall color correction amount Δ
Where B and ΔR are ΔB = ΔB ₁ + ΔB ₂ , ΔR = ΔR ₁ + ΔR ₂
The control signal i is created according to the correction amounts ΔB and ΔR thus obtained (S228 to S232), and the process returns. If the film type is black and white (W.
B), create control data for deleting the color information (S238), and return.

Next, "display control I" and "display control II" will be described with reference to FIGS. In FIG. 56, first,
It is determined based on the input data from the microcomputer (μC1) 1 whether or not recording is in progress (S250). If recording is in progress, the process directly returns. If not recording, the process proceeds to S252. In step S252, a flag DPIF indicating that a still image is being displayed is displayed.
Is set, and if it is set, this flag DPIF is reset, that is, the still image display mode is exited (S254), and then the input destination of the data instructing the display is set from the frame memory 122 to the frame. Data for switching to the memory 121 is set (S256), and the process returns. If the flag DPIF is not set in S252, this flag D
The PIF is set (S258), then the data for switching the input destination of the data instructing the display from the frame memory 121 to the frame memory 122 is set (S260), and the process returns.

In FIG. 57, first, it is determined whether or not this routine showing the change of the still image is passed once by the flag DP1.
It is determined from the state of stF (S270), and when it has not passed yet, it is determined whether or not a change operation, that is, whether the switch DP _UP is turned on from off (S27).
2). If the switch DP _UP has not been turned on from off, the routine proceeds to S278, where a flag DP1st indicating that this routine has been passed is set and the routine returns. If the switch DP _UP is turned on from off, the currently displayed read address of the internal memory 129 is increased and addressing is performed (S274). Then, the display switching data for transferring the image stored in the designated address of the internal memory 129 to the frame memory 122 is set (S276), and the process proceeds to S78.
The frame memory 122 outputs the image data while inputting the image data from the internal memory 129,
indicate. When the flag DP1stF is set in S260, the flag DP1stF is reset (S280) and the process returns.

The control operation of the microcomputer (μC21) 120 has been described in connection with the microcomputer (μC2) 100, and therefore its explanation is omitted. Microcomputer (μ
In C21) 120, based on the input data from the microcomputer (μC2) 100, the above-described insertion of the character into the monitor 47, addition / subtraction of image data, color conversion, control of the frame memories 121 and 122, display switching control, Control of the adder circuit 124, control of the switch 125, storage control of the IC card 51, control of the internal memory 129, etc. are performed.

Next, with reference to FIGS. 58A and 58B, the microcomputer (μC3) 140 of the transceiver TX and the transceiver RX will be described.
The control of the microcomputer (μC4) 150 will be described.
(A) is a control flow of the microcomputer (μC3) 140,
(B) shows a control flow of the microcomputer (μC4) 150.

The microcomputer (μC3) 140 uses the switch S
_{When the REM} turns from off to on, an interrupt “S _REM INT” is executed, and when the vertical synchronization signal V _sync from the timing control is input (# R2), control data is wirelessly transmitted to the transmitter / receiver R.
It is output to X, and then one screen of image data is output (# R4, # R6). Next, switch data is wirelessly input from the transceiver RX, and this switch data is output to the microcomputer (μC1) 1 (# R8, # R10),
Return to # R2.

The microcomputer (μC4) 150 is a transceiver T
When an interrupt occurs due to the wireless control data from X, the control data is input and then the image data is input (# R2
0- # R22). Next, the microcomputer (μC4) 150 detects the states of various switches, stores the detection results in the built-in RAM, and wirelessly transmits and receives these switch data.
Output to X and shift to the interrupt standby state (# R24-
# R28). As described above, the transceiver RX does not perform calculations by operating the switches, outputs only switch data to the transceiver TX, and controls the transmitter / receiver TX according to the state of the switch.

In the above embodiment, CC is used as the image sensor.
Since a D (solid-state image sensor) type is used,
When the exposure time is longer than 1/60 in still shooting mode, the image obtained every 1/60 is read and added to the previous image to obtain an appropriate exposure, and the image obtained every 1/60 Although the gain is digitally adjusted for proper exposure, a nondestructive image sensor shown in FIG. 59 may be used instead. This type of sensor can read data every 1/60 while accumulating accumulated charges due to light. Therefore, if the read data is treated as an image and exposure is continued, a still image with proper exposure can be obtained. Is obtained.

FIG. 59 shows the image sensor 3 of this nondestructive type.
00 structure, (a) is a schematic sectional view, (b)
Is the equivalent circuit. For convenience of description, the description will be given below based on the definition of Expression 1.

[0144]

[Equation 1]

The image sensor 300 comprises photoelectric conversion cells in a matrix, and the photoelectric conversion cells are arranged and formed on the n ₊ silicon substrate 301. Each cell has SiO ₂ , S
Element isolation region 30 made of i ₃ N ₄ or polysilicon
2 electrically insulates cells adjacent to each other. Each cell has the following structure. An n ₋ region 303 having a low impurity concentration is formed on the n ₊ silicon substrate 301 by an epitaxial technique or the like, and a p region 304 is formed by doping p type impurities on the n ₋ region 303.
An n ₊ region 305 is formed in the p region 304 by an impurity diffusion technique or an ion implantation technique. P region 304 and n ₊ region 305 are the base and emitter of the bipolar transistor, respectively. An oxide film 306 is formed on the n ₋ region 303 in which each region is formed in this way, and a capacitor electrode 307 having a predetermined area is formed on the oxide film 306. Capacitor electrode 307
Opposes the p region 304 across the oxide film 306 and controls the potential of the p region 304 in a floating state by applying a pulse voltage to the capacitor electrode 307. In addition, the emitter electrode 308 connected to the n ₊ region 305 and the substrate 301
An n ₊ region 311 having a high impurity concentration and a collector electrode 312 for applying a potential to the collector of the bipolar transistor are formed on the back surface of the bipolar transistor.

Next, the basic operation will be described. First, it is assumed that the p region 304, which is the base of the bipolar transistor, is in the initial state of negative potential. Light 313 enters from the p region 304 side, holes of the electron-hole pairs generated by the incident light are accumulated in the p region 304, and the accumulated holes cause the potential of the p region 304 to be in the positive direction. Rises to (accumulation operation). Then, a positive voltage pulse for reading is applied to the capacitor electrode 307, and a reading signal corresponding to the change in the base potential during the accumulation operation is output from the floating emitter electrode 308 (reading operation). However, since the accumulated charge amount of the p region 304 which is the base hardly decreases, the read operation can be repeated. To remove the holes accumulated in the p region 304, the emitter electrode 308 is grounded and a positive voltage refresh pulse is applied to the capacitor electrode 307. By applying this pulse, the p region 304 is biased in the forward direction with respect to the n ₊ region 305, and the accumulated holes are removed. And
When the refresh pulse falls, the p region 30
4 returns to the initial state of negative potential (refresh operation). Thereafter, the operations of accumulating, reading and refreshing are similarly repeated.

Further, as another method of the exposure operation, the exposure is cut off at 1/60, and the AGC is performed as in a normal moving image.
A gain of 1 may be set in the circuit 105 (the AGC circuit 109 is not necessary), and it may be determined by this gain whether or not the exposure is within the proper range. Within the range of proper exposure, both moving images and still images are appropriate for exposure. On the other hand, in this case, a still image shot on a silver halide film has a different degree of image shake due to a difference in shutter speed. Therefore, when the shutter speed becomes slow enough to cause the problem of image blur, an alarm display may be provided to inform the photographer of the fact.

[0148]

As described above, according to the present invention,
On the display member as a monitor, a still image display for displaying the captured image as a still image to confirm the captured image on the photosensitive medium and a moving image display for displaying the moving image being recorded on the moving image recording medium are selectively provided. Since this is performed, it is possible to provide a highly practical video-integrated camera in which the function as a video monitor and the function as a camera monitor can be appropriately used according to the purpose of use.

[Brief description of drawings]

FIG. 1 is a circuit block diagram of a video-integrated camera according to the present invention.

FIG. 2 is a front perspective view showing an external configuration of a camera to which the present invention is applied.

FIG. 3 is a rear perspective view showing an external configuration of a camera to which the present invention is applied.

FIG. 4 is an enlarged view of a grip portion in an external configuration of a camera to which the present invention is applied.

FIG. 5 is an external view showing transceivers TX and RX that perform image transmission, FIG. 5A is a transceiver TX on the camera body side, and FIG.
Indicates a remote control transceiver RX.

FIG. 6 is a front perspective view of the camera body with transceivers TX and RX attached.

FIG. 7 is a rear perspective view of the camera body with transceivers TX and RX attached.

FIG. 8 is a diagram showing an internal structure related to a photographing lens and an optical system in a camera body.

9A and 9B are configuration diagrams showing an example of a CCD, FIG. 9A is a partially cutaway plan view, FIG. 9B is a side sectional view, and FIG. 9C is a plan view illustrating the relationship between areas.

FIG. 10 is a diagram showing a line-of-sight area and a corresponding positional relationship of the areas of the AF sensor and the AE sensor with respect to the line-of-sight area.

FIG. 11 is a diagram showing characters such as marks that can be displayed on a monitor.

FIG. 12 is a diagram showing a state in which a line-of-sight detection area frame is displayed on a monitor.

FIG. 13 is a diagram showing a state where the line-of-sight area is displayed on the monitor.

FIG. 14 is a circuit configuration diagram of a CCD / monitor / recording unit.

FIG. 15 is a block diagram of a transceiver TX.

FIG. 16 is a block diagram of a transceiver RX.

FIG. 17 is an internal circuit diagram of a photometric and dimming circuit.

FIG. 18 is an interrupt routine executed when a switch S ₁ , a recording start switch or a grip switch is turned on.

FIG. 19 shows a “switch data input” subroutine.

FIG. 20 shows a subroutine of “S _REM ”.

FIG. 21 shows a subroutine of “eyepiece”.

FIG. 22 shows a subroutine of “exposure calculation”.

FIG. 23 is a diagram showing a program diagram.

FIG. 24 shows a subroutine of “AF1”.

FIG. 25 shows a “shooting preparation” subroutine.

FIG. 26 shows a subroutine of “visual axis detection”.

FIG. 27 shows a "shooting mode setting" subroutine.

FIG. 28 shows a subroutine of “exposure mode setting”.

FIG. 29 shows a subroutine of “AV / TV setting”.

FIG. 30 shows a subroutine of “AF / AE”.

FIG. 31 shows a “focus detection” subroutine.

FIG. 32 shows a subroutine of “photometry”.

FIG. 33 shows a “playback” subroutine.

FIG. 34 shows a subroutine of “S1ON”.

FIG. 35 shows a subroutine of “S1ON”.

FIG. 36 shows a “photographing” subroutine.

FIG. 37 shows a “photographing I” subroutine.

FIG. 38 shows a "winding" subroutine.

FIG. 39 shows a “preview” subroutine.

FIG. 40 shows a subroutine of “exposure compensation”.

41A to 41D are charts showing the spectral characteristics of each light source.

42A and 42B are charts showing examples of the spectral sensitivity of a daylight type film and a tungsten type film.

FIG. 43 shows a “color correction” subroutine.

FIG. 44 shows a “REC” subroutine.

FIG. 45 shows a subroutine of “REC”.

FIG. 46 shows a “data interrupt” subroutine.

FIG. 47 shows a flowchart of “interrupt (power supply)”.

FIG. 48 shows a subroutine of “exposure control I”.

FIG. 49 is a timing chart illustrating the outline of the operation of the CCD / monitor / storage unit.

FIG. 50 shows a subroutine of “V _SYNC interrupt”.

FIG. 51 shows a subroutine of “V _SYNC interrupt”.

FIG. 52 shows a “memory control” subroutine.

FIG. 53 shows a subroutine of “PV control”.

FIG. 54 shows a subroutine of “exposure correction”.

FIG. 55 shows a “color correction” subroutine.

FIG. 56 shows a “display control I” subroutine.

FIG. 57 shows a “display control II” subroutine.

58 (a) and (b) are flowcharts showing the control of the transceivers TX and RX.

FIG. 59 is a diagram showing the structure of a non-destructive imaging sensor 300 which is another embodiment of the imaging member used in the present invention.
(A) is a schematic sectional view and (b) is an equivalent circuit thereof.

[Explanation of symbols]

1 Microcomputer (μC1) 2 Line-of-sight detection circuit 3 Eyepiece detection circuit 4 Exposure drive unit 5 Winding circuit 6 Film sensitivity reader 7 LEMI 8 LEMII 9 Photometric and dimming circuit 10 CCD / monitor / storage unit 11 Inverter 12, 13 Encoder 14 AND Circuit 15 Power supply 16, 17 Storage control unit 18 Shooting screen 19 Line-of-sight detection area frame 191,192 Frame ARN (N = 1 to 16) Line-of-sight area AF1 to AF5 AF area 20 Camera body 21 Shooting lens unit 211 Shooting lens 22 Grip unit 23 the release button 24 the body display unit 25 displays operating member (switch S _DPI) 26 memory changing switch (switch S _DPUP) 27 preview switch (switch S _PV) 28 viewfinder 29 eye sensor 30 line of sight operation member (switch S _SDI) 32 flash Road 33 Front dial 34 Rear dial 35 Color correction switch 36, 37 Exposure change switch 38 Exposure mode change switch 39 Recording start switch 40 Shooting mode change switch 41 Optical axis 42 Half mirror 43 CCD (image pickup member) 300 Image pickup member 44 Reduction optical system 45 film 46 focal plane shutter 47,154 monitor 100 microcomputer (μC2) 101,102 timing signal generation circuit 103 CDS circuit 104 WB circuit 105,109 AGC circuit 107 γ circuit 108 matrix circuit 110 image compression circuit 111,121,122,123 Frame memory 116 Digital modulation circuit 117 Recording head 120 Microcomputer (μC21) 124 Adder circuit 125 Switch circuit 126 Image compression / expansion circuit 127 Video reproduction Circuit 128 Switching circuit 129 Internal memory 140 Microcomputer (μC3) 141 Memory 142, 151 Transmitter / receiver circuit 150 Microcomputer (μC4) 152 Memory AR1C to AR15C Photometric circuit SPC1 to SPC15 Photometric element TX, RX Transceiver 50 Electronic information recording unit 51 IC card 52 Magnetic recording medium

Claims (1)

[Claims] 1. A light-sensitive medium on which an image of one light flux that has passed through a taking lens and which is divided into two on the way is captured, an imaging member for capturing an image of the other light flux, and the above-mentioned imaging. A display member for displaying an image picked up by the member on a monitor; and a still image display means for displaying the image picked up by the image pick-up member on the display member at any timing in order to confirm the picked-up image on the photosensitive medium. A moving image recording means for sequentially recording the picked-up images on a moving image recording medium, a moving image display means for displaying a recorded image on the moving image recording medium as a moving image, and the still image. A video-integrated camera comprising a display and a display selection means for selectively displaying the moving image.