JP2005024857A - Digital single lens reflex camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital single lens reflex camera which prevents exposure from being deviated from appropriate exposure in the midst of consecutive image pickup and whose handleability is good for a photographer. <P>SOLUTION: The digital single lens reflex camera is equipped with an imaging means 27 picking up an object image, a display means 8, a consecutive imaging control means 41, a luminance detection means detecting the average luminance value of the specified area of the picked-up electronic image, a comparison means 41 and a correction means 41 correcting the exposure in imaging operation performed continuously when the change of the luminance value is decided by the comparison means 41. The consecutive imaging control means 41 is constituted to repeat imaging operation by the imaging means 27 and picture display operation by the display means 8 in a state where a movable mirror 24 is still moved to a mirror-up position. The comparison means 41 compares the first luminance value immediately after starting the consecutive imaging with the newest luminance value in the midst of the consecutive imaging operation detected by the luminance detection means, and decides whether or not the newest luminance value is changed more than the first luminance value. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital single-lens reflex camera, and more particularly to a digital single-lens reflex camera that observes a subject using a finder optical system and picks up a subject image using a solid-state image sensor.
[0002]
[Prior art]
As is well known, a finder device for a single-lens reflex camera using a silver salt film is generally an optical finder that uses an optical member such as a pentaprism or a porro prism to observe an optical subject image. A finder device for a digital single-lens reflex camera is a so-called electronic viewfinder in which a display element is further arranged on an optical finder device, an output of an image sensor is displayed on the display element, and an electronic subject image is observed from the finder. It is also possible to configure as. There are also known finder apparatuses that can arbitrarily switch between the state of the electronic viewfinder and the state of the optical viewfinder.
[0003]
By the way, a digital single-lens reflex camera sharing an optical viewfinder and an electronic viewfinder has an advantage that the speed of continuous imaging (continuous shooting) can be increased.
[0004]
In view of such advantages, the present applicant keeps the movable mirror of the optical finder retracted from the imaging optical path with the start of the continuous shooting operation, and at that time, the captured electronic image is an optical subject by the optical finder. Japanese Patent Application Laid-Open No. 2004-228867 proposes a finder apparatus that shares an optical viewfinder and an electronic viewfinder, in which an electronic subject image is observed with an electronic viewfinder instead of an image.
[0005]
If the finder device is configured in this way, it is not necessary to move the movable mirror up and down during continuous shooting, so that noise and vibration due to the movable mirror operating at high speed can be suppressed, and the continuous shooting speed can be increased. There is a great advantage.
[0006]
[Patent Document 1]
Japanese Patent Application No. 2002-6502
[0007]
[Problems to be solved by the invention]
By the way, in order to increase the continuous shooting speed, it is not possible to execute the exposure amount calculation and the exposure amount control based on the photometric operation and the photometric result every time of imaging, so during continuous shooting, In general, a shutter and an aperture are fixed to an exposure amount measured before the start of continuous shooting.
[0008]
However, in continuous shooting, the subject often moves, and if the subject moves during continuous shooting, the subject brightness often changes, and continuous shooting is performed with the exposure amount set before the start of continuous shooting. If this is done, the longer the continuous shooting, there is a possibility that a photograph of overexposure or underexposure will be taken, which is a problem of continuous shooting operation for the photographer. Further, this is not taken into consideration in the above-mentioned Patent Document 1.
[0009]
The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an easy-to-use digital single lens camera that can prevent the exposure amount from deviating from the appropriate exposure amount during continuous imaging. To provide a reflex camera.
[0010]
[Means for solving the problems and actions]
In order to achieve the above object, a digital single-lens reflex camera according to the present invention is based on an imaging unit that captures a subject image and converts it into digital image data, a photometric unit that measures the subject, and an output of the photometric unit, A calculation means for calculating an exposure amount at the time of an image pickup operation by the image pickup means, a finder optical system, and a finder optical system which is in an image pickup optical path of the image pickup means and guides a subject luminous flux to the finder optical system when observing a subject. And a display element for displaying the digital image data converted by the imaging means at a position 1 and a movable mirror that moves to the second position retracted from the imaging optical path during the imaging operation by the imaging means Display means arranged so that an image displayed on the display element can be observed by sharing a part of the observation optical path of the finder optical system, and the movable mirror A continuous imaging control unit that executes a continuous imaging operation that repeats an imaging operation by the imaging unit and an image display operation by the display unit while being moved to a second position; and a luminance level of an electronic image captured by the imaging unit The first luminance value immediately after the start of continuous imaging detected by the luminance detecting unit and the latest luminance value during the continuous imaging operation are compared, and the latest luminance value is A comparison unit that determines whether or not the luminance value has changed from the first luminance value, and a comparison unit that determines whether or not the luminance value has changed from the first luminance value. Correction means for correcting the exposure amount of the image pickup operation by the image pickup means.
[0011]
The digital single-lens reflex camera according to the present invention includes an imaging unit that captures a subject image and converts it into digital image data, a photometric unit that measures the subject, and an imaging operation by the imaging unit based on the output of the photometric unit. A calculation means for calculating an exposure amount at the time, a finder optical system, and an imaging optical path of the imaging means, and a first position for guiding a subject luminous flux to the finder optical system when observing the subject, A movable mirror that moves to a second position retracted from the imaging optical path during an imaging operation by the imaging means, and a display element for displaying the digital image data converted by the imaging means. The display means disposed so that the image displayed on the finder optical system can be observed by sharing a part of the observation optical path of the finder optical system, and the movable mirror is moved to the second position. A continuous imaging control unit that executes a continuous imaging operation that repeats an imaging operation by the imaging unit and an image display operation by the display unit, and an average luminance value of a specific area in the electronic image captured by the imaging unit. The brightness detection means to detect, the first brightness value immediately after the start of continuous imaging detected by the brightness detection means, and the latest brightness value during the continuous imaging operation are compared, and the latest brightness value is the first brightness value The comparison means for determining whether or not the brightness value is changed to a value that is more than the appropriate exposure range than the brightness value, and the comparison means means that the latest brightness value is more than the value that becomes the appropriate exposure range than the first brightness value. And a correction unit that corrects an exposure amount of an imaging operation performed by the imaging unit that is subsequently performed when it is determined that the change has occurred.
[0012]
In addition, an autofocus device is further provided, and the specific area in the electronic image is made to coincide with the range-finding range of the autofocus device, and the luminance detecting means is characterized in that the specific area in the electronic image is The output level from the pixels in the area is averaged and output, and the correction means changes the shutter speed and / or aperture value according to the set shooting mode. And
[0013]
The digital single-lens reflex camera according to the present invention further includes an imaging unit that captures a subject image and converts it into digital image data, a photometric unit that measures the subject, and an imaging operation performed by the imaging unit based on an output of the photometric unit. A calculation means for calculating an exposure amount at the time, a finder optical system, and an imaging optical path of the imaging means, and a first position for guiding a subject luminous flux to the finder optical system when observing the subject, A movable mirror that moves to a second position retracted from the imaging optical path during an imaging operation by the imaging means, and a display element for displaying the digital image data converted by the imaging means. Display means arranged so that the image displayed on the finder optical system can be shared by sharing a part of the observation optical path of the finder optical system, and the movable mirror is moved to the second position. The continuous imaging control means for executing the continuous imaging operation for repeating the imaging operation by the imaging means and the image display operation by the display means, and the luminance level in a part or all of the electronic image captured by the imaging means And a correcting means for correcting an exposure amount in a subsequent imaging operation in accordance with an output of the brightness detecting means during the continuous imaging operation.
[0014]
The digital single-lens reflex camera according to the present invention includes an imaging unit that captures a subject image and converts it into digital image data, a photometric unit that measures the subject, and an imaging operation by the imaging unit based on the output of the photometric unit. A calculation means for calculating an exposure amount at the time, a finder optical system, and an imaging optical path of the imaging means, and a first position for guiding a subject luminous flux to the finder optical system when observing the subject, A movable mirror that moves to a second position retracted from the imaging optical path during an imaging operation by the imaging means, and a display element for displaying the digital image data converted by the imaging means. The display means disposed so that the image displayed on the finder optical system can be observed by sharing a part of the observation optical path of the finder optical system, and the movable mirror is moved to the second position. A continuous imaging control unit that executes a continuous imaging operation that repeats an imaging operation by the imaging unit and an image display operation by the display unit, and a first electronic image captured by the imaging unit during the continuous imaging operation; Comparing the latest electronic images, when the brightness levels of the two images are different from each other, there is provided correction means for correcting an exposure amount in a subsequent imaging operation.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
First, before describing embodiments of the present invention, features of a digital single-lens reflex camera to which the present invention is applied will be described.
This digital single-lens reflex camera is a camera that captures a subject image with an image sensor such as a CCD. The camera is provided with a release button for instructing the start of an imaging operation on the exterior casing of the camera. As the imaging mode, “continuous imaging mode (hereinafter referred to as continuous shooting mode)” in which the imaging operation is repeated while the release button is kept pressed, and the imaging operation is executed only once by operating the release button. "Single-shot mode (hereinafter referred to as single-shot mode)" can be selected, and a continuous / single-shot switching button for this purpose is provided.
[0016]
Then, while the release button is operated with the “continuous shooting mode” selected by the continuous / single shooting switch button, the movable mirror for observing the subject image is kept retracted from the imaging optical path. The imaging operation is repeated. Therefore, during continuous shooting, the camera operator cannot confirm the optical subject image by the finder optical system, but with this digital single-lens reflex camera, a display for displaying the captured image in the finder immediately after imaging. Means are provided so that during continuous shooting, the photographer visually recognizes the electronic subject image on the display means instead of the optical subject image.
[0017]
The present invention will be described below with reference to the illustrated embodiments.
FIG. 1 is a perspective view of a digital single-lens reflex camera showing an embodiment of the present invention as seen from the back side.
As shown in FIG. 1, a release button 303 composed of a two-stage switch for instructing the start of an imaging operation is arranged near the upper right end of the outer casing 301 of the digital single-lens reflex camera 300. A mode button 302 for setting a shooting mode is provided near the left end of the upper surface. In the vicinity of the left side of the release button 303, when a shutter speed priority shooting mode (hereinafter referred to as a Tv mode) is set with the mode button 302, an aperture setting button (hereinafter referred to as an aperture value) for changing the aperture value. A shutter speed setting button (hereinafter referred to as a Tv setting button) for changing a shutter speed when an aperture priority shooting mode (hereinafter referred to as an Av mode) is set by an 305 and mode button 302. 306) is provided. A continuous / single shooting switch button 307 for setting the continuous shooting mode or the single shooting mode is disposed near the left of the Av setting button 305 and the Tv setting button 306.
[0018]
The mode button 302 is a button for setting the shooting mode to a program shooting mode (hereinafter referred to as P mode) / manual shooting mode (hereinafter referred to as M mode) / Tv mode / Av mode. Further, a finder eyepiece 304 for observing a subject image, which has a finder eyepiece 33, is disposed on the rear side of the outer casing 301 on the upper left side of the approximate center.
[0019]
FIG. 2 is a block diagram showing an outline of a configuration of an electric circuit of the digital single-lens reflex camera of FIG.
As shown in FIG. 2, the digital single-lens reflex camera 300 includes a CPU 41 that controls the operation sequence of the entire camera, a strobe light emitting unit 1, a photographing lens barrel 20, a movable mirror 24, a shutter 26, and an imaging unit. Solid-state imaging device 27, finder 30, zoom / focus drive circuit 34, aperture drive circuit 35, mirror drive circuit 36, AF sensor drive circuit 37, shutter drive circuit 38, focus detection device 39, and switch The input unit 42, the EEPROM 43, the signal processing circuit 45, the strobe control circuit 46, the EPROM 47, the SDRAM 48, and the flash memory 50 constitute the main parts.
[0020]
The taking lens barrel 20 includes a positive lens 21 and a negative lens 23, and a diaphragm mechanism 22 is disposed between the positive lens 21 and the negative lens 23. The positive lens 21 and the negative lens 23 of the photographic lens barrel 20 are driven and controlled by a zoom / focus drive circuit 34, and the aperture mechanism 22 is driven and controlled by an aperture drive circuit 35.
[0021]
At the rear of the negative lens 23 on the optical axis of the positive lens 21 and the negative lens 23, a movable mirror 24, which is formed entirely of a half mirror, is a first position, a mirror down position and a second position. It is arrange | positioned so that it can move to the position of the mirror up which is. At the time of exposure, the movable mirror 24 jumps from the first position to the second position, which is the mirror-up position, toward the focusing screen 31 while rotating around the fixed shaft 24a, and is retracted from the photographing optical path. Yes. A sub mirror 25 is provided on the back of the central portion of the movable mirror 24 so as to reflect the subject light downward in the figure.
[0022]
Below the reflected optical axis of the sub-mirror 25, a separator optical system 28 for separating two images is disposed in a substantially vertical direction in the drawing, and a subject image is connected by the separator optical system 28. An AF sensor 29 is disposed at the image position, and an AF sensor driving circuit 37 is connected to the AF sensor 29. The sub mirror 25, the separator optical system 28, and the AF sensor 29 constitute a focus detection device 39 that is an autofocus device. The AF sensor drive circuit 37 uses a known phase difference method via the focus detection device 39 to measure the range (range) of the subject defined by the AF target mark 201 (see FIG. 4), which is a specific area in the electronic image. Thus, the focal length of the subject is detected.
[0023]
The AF sensor 29 is driven and controlled by an AF sensor driving circuit 37 in accordance with a control signal from a control circuit (CPU) 41 composed of a microprocessor described later. The CPU 41 obtains the interval between the two images (corresponding to the defocus amount of the positive and negative lenses 21 and 23) based on the two image signals generated by the AF sensor 29, and sets the photographing lens barrel 20 at the in-focus position. Drive amount data for driving the positive lens 21 and the negative lens 23 is calculated. Then, the zoom / focus drive circuit 34 is driven and controlled based on the calculated drive amount data to drive the positive and negative lenses 21 and 23 of the photographic lens barrel 20 to the in-focus position.
[0024]
The zoom / focus drive circuit 34 includes a drive source such as a known electromagnetic motor and ultrasonic motor, a driver circuit for controlling these drive sources, an encoder device for detecting the position of the lens, and the like. It is configured. In particular, the encoder for detecting the lens position is an encoder device that independently outputs the subject distance and the zoom focal length according to the lens position, and is a piece on the metal pattern provided on the outer surface of the lens frame. This is a contact type encoder that the brush slides. Further, a non-contact encoder may be used in which a black and white pattern is arranged on the outer surface of the photographing lens barrel 20 and the black and white pattern is detected by a photo reflector, and the driving amount of the photographing lens barrel 20 from the reference position is measured. Then, a so-called absolute distance encoder that detects the absolute position may be used.
[0025]
A finder optical system including a focusing screen (focusing screen) 31, a pentaprism 32, and a finder eyepiece 33 is disposed on the reflection optical path of the movable mirror 24. A finder device (hereinafter referred to as a finder) 30 is configured by adding an LCD monitor 8, a prism 54, a target lens 55, and a photometric sensor 56, which is a photometric means, to the finder optical system. The subject light obtained by the positive lens 21 and the negative lens 23 of the photographic lens barrel 20 is reflected by the movable mirror 24 and imaged on the focusing screen 31. The photographer visually recognizes the optical subject image formed on the focusing screen 31 from the observation optical axis through the pentaprism 32 and the viewfinder eyepiece 33. An AF target mark 201 shown in FIG. 4 to be described later is ruled (or engraved) on the surface of the focusing screen 31 on the pentaprism 32 side.
[0026]
The photometric sensor 56 is a sensor in which, for example, a light receiving surface is formed of a photodiode for measuring the luminance of an optical subject image formed on the focusing screen 31 through the target lens 55. The eyepiece lens 33 is disposed together with the target lens 55 at a position on the photometric axis that is decentered from the observation optical axis. The CPU 41 calculates the exposure amount during the imaging operation by the solid-state imaging device 27 by performing, for example, a predetermined weighted average calculation according to the output from the photometric sensor 56. Therefore, the CPU 41 constitutes a calculation means.
[0027]
Behind the movable mirror 24 on the optical axis of the positive lens 21 and the negative lens 23 of the taking lens barrel 20 is a solid-state image pickup device (hereinafter referred to as an image pickup device) which is an image pickup means such as a shutter 26 and a CCD or CMOS imager. 27 is disposed.
[0028]
The shutter 26 is opened for a predetermined time by the shutter drive circuit 38 to form a subject image on a light receiving surface (not shown) of the image sensor 27. That is, the movable mirror 24 is raised to the second position in order to retract from the optical axes of the positive and negative lenses 21 and 23 under the driving of the mirror driving circuit 36, and the shutter 26 is based on the driving control of the shutter driving circuit 38. In the open state, a subject image is formed on the light receiving surface of the image sensor 27, and an imaging operation is performed. When the continuous shooting mode is set by the continuous / single shooting setting button 307, the image pickup operation by the image pickup device 27 is continuously performed while the movable mirror 24 is raised (moved) to the second position. Done.
[0029]
The zoom / focus drive circuit 34, the aperture drive circuit 35, the mirror drive circuit 36, the AF sensor drive circuit 37, and the shutter drive circuit 38 are connected to a CPU 41 constituted by a microprocessor via a data bus 52. The CPU 41 is connected to a switch input means 42 and an EEPROM 43 which is a nonvolatile memory via a data bus 52.
[0030]
The switch input means 42 includes a first release switch that is turned on in conjunction with a half-pressing operation of a release button 303 (see FIG. 1) of the camera, a second release switch that is turned on in conjunction with a deep-pressing operation of the button, A switch linked to the power switch, a switch linked to the continuous / single shooting switch button 307 for switching between the single shooting mode and the continuous shooting mode, and a mode button 302 (see FIG. 1) of the camera for setting the shooting mode. It is composed of a plurality of switches such as interlocking mode switches (all not shown), and supplies an operation signal to the CPU 41 based on any switch operation of the switch input means 42.
[0031]
The EEPROM 43 is a non-volatile semiconductor memory, and the CPU 41 controls the amount of light of the backlight 8b based on the adjustment value for each camera and the output from the photometric sensor 56, which are necessary for shipping while suppressing the variation of each camera in the factory. Stores the coefficient to define.
[0032]
When the first release switch is turned on, the CPU 41 drives and controls the AF sensor drive circuit 37, and an AF target mark 201 shown in FIG. 4 (described later) of an electronic subject image (electronic image) formed on the AF sensor 29 is displayed. The distance between the two images is calculated from the prescribed distance measurement area, and the zoom / focus drive circuit 34 is driven and controlled based on the distance data to adjust the focus of the positive lens 21 and the negative lens 23 of the photographing lens barrel 20. Do.
[0033]
Further, when the second release switch is turned on, the CPU 41 drives and controls the mirror drive circuit 36 to move the movable mirror 24 to the second position from the optical axis, and based on the output of the photometric sensor 56. Based on the subject luminance information, an appropriate aperture value and a shutter speed are obtained, the aperture mechanism 22 is driven through the aperture drive circuit 35 with the obtained aperture value, and the shutter through the shutter drive circuit 38 at the shutter speed. 26 is driven. Further, the amount of current (light quantity) supplied to the backlight 8 b of the LCD monitor 8 is determined with reference to the coefficient stored in the EEPROM 43. Further, by comparing the first luminance value immediately after the start of continuous imaging input from the CPU 100 (see FIG. 3) of the signal processing circuit 45 described later with the latest luminance value during the continuous imaging operation, the latest luminance value is obtained. It is determined whether or not has changed to a value that is within the appropriate exposure range from the first luminance value. If the luminance value has changed, the CPU 41 changes the value of the aperture mechanism 22 via the aperture drive circuit 35 in order to correct the exposure amount of the imaging operation performed by the solid-state imaging device 27 that is subsequently performed, and the shutter drive circuit. The shutter speed of the shutter 26 is changed via 38. Therefore, the CPU 41 constitutes continuous imaging control means, comparison means, and correction means.
[0034]
When the subject image is formed on the light receiving surface of the image sensor 27 by the opening operation of the shutter 26, the subject image is converted into an analog video signal, and further converted into a digital video signal in the signal processing circuit 45.
[0035]
The signal processing circuit 45, which will be described in detail later with reference to FIG. 3, includes a RISC processor, a color processor, and a JPEG processor, and performs compression / decompression processing, white balance processing, edge enhancement processing, etc. of the digital video signal. Image processing, conversion processing to a composite signal (luminance signal, color difference signal) output to the LCD monitor 8 described later, and the like are performed.
[0036]
Further, the CPU 41 and the signal processing circuit 45 are connected via a communication line 53, and control signals such as video signal capture timing and data are transmitted and received via the communication line 53.
[0037]
The composite signal generated by the signal processing circuit 45 is output to the LCD monitor 8 which is a display means in the finder 30 to display an electronic subject image. The LCD monitor 8 is disposed outside the third reflecting surface 32 a of the pentaprism 32. The LCD monitor 8 includes an LCD (liquid crystal display element) 8a that is a display element for displaying an image, and a backlight 8b of, for example, a white LED for illuminating the display surface of the LCD 8a from the rear. Has been. When the continuous shooting mode is set by the continuous / single shooting setting button 307 of the switch input means 42, the image is displayed on the LCD monitor 8 while the movable mirror 24 is raised (moved) to the second position. The operation is performed continuously.
[0038]
The third reflecting surface 32 a of the pentaprism 32 is a half mirror, and a prism 54 including a convex lens surface 54 a is disposed between the pentagonal prism 32 and the LCD monitor 8. The LCD 8a of the LCD monitor 8 is positioned optically equivalent to the focusing screen 31 by the convex lens surface 54a. In the state where the movable mirror 24 is raised from the first position to the second position and the optical observation optical path is blocked, the image displayed on the LCD monitor 8 can be observed. The brightness of the image displayed on the LCD 8a can be adjusted by changing the current supply amount of the white LED of the backlight 8b.
[0039]
The signal processing circuit 45 is connected to an EPROM 47, an SDRAM (Synchronous Dynamic Random Access Memory) 48, and a flash memory 50 via a data bus 51.
[0040]
The EPROM 47 stores a program to be processed by a processor included in the signal processing circuit 45. Further, the first luminance value immediately after the start of continuous imaging input from the CPU 100 (see FIG. 3) of the signal processing circuit 45 is compared with the latest luminance value during the continuous imaging operation, and the latest luminance value is the first luminance value. A predetermined value α serving as a reference value for determining whether or not the brightness value has changed to a value that is equal to or greater than the appropriate exposure range is stored, and the latest brightness value is the first brightness value. In addition, a correction table (Tv correction table / Av correction table) for changing the shutter speed and / or the aperture value in accordance with each photographing mode when the exposure value is changed to a value that becomes an appropriate exposure range or more is stored. Has been.
[0041]
The SDRAM 48 is a memory that temporarily stores image data before image processing and image data during image processing. Therefore, as will be described later, when the continuous shooting mode is set, the continuously captured image data is temporarily stored in the SDRAM 48. The flash memory 50 is a non-volatile memory that stores finally finalized image data. Here, the SDRAM 48 is a volatile temporary storage means that can operate at high speed, but the stored contents disappear when the power supply is stopped. On the other hand, the flash memory 50 is a non-volatile storage means, and the stored contents are preserved even if the power of the camera is turned off at a low speed. Therefore, after the continuous imaging is completed, the image data stored in the SDRAM 48 is sequentially stored in the flash memory 50.
[0042]
Next, the strobe light emitting unit 1 will be described. The strobe light emitting unit 1 includes a light emitting panel 3, a reflector 18, a light emitting discharge tube 19, and a trigger circuit 44. The strobe light emitting unit 1 is sealed in the light emitting discharge tube 19 by a trigger signal output from the trigger circuit 44. The xenon gas is excited to emit light, and the light is reflected by the reflector 18 and further passes through the light emitting panel 3 and is irradiated toward the subject. Although not shown, the trigger circuit 44, the light-emitting discharge tube 19, the reflector 18 and the light-emitting panel 3 are configured to pop up from the camera body, for example. The trigger circuit 44 is connected to the strobe control circuit 46. The strobe control circuit 46 controls charging of a strobe main capacitor (not shown) and a light emission instruction to the trigger circuit 44 under the control of the CPU 41.
[0043]
FIG. 3 is a block diagram showing a schematic configuration of the electric circuit of the signal processing circuit 45 in FIG. 2 and peripheral circuits connected thereto.
[0044]
The signal processing circuit 45 includes a CPU 100 as a control circuit that controls signal processing operations, and a plurality of circuits that are connected to the CPU 100 and operate according to control signals from the CPU 100. Further, as shown in FIG. 2 described above, the CPU 100 is connected to the camera sequence control CPU 41 via the communication line 53, and each circuit in the signal processing circuit 45 is based on the control signal transmitted from the CPU 41. To control. In addition, the luminance value of the electronic image output from the luminance detection circuit 108 described later is output to the CPU 41.
[0045]
The first image processing circuit 101 drives the imaging device 27 according to the driving conditions set by the CPU 100, and A / D converts the analog video signal output from the imaging device 27 to generate a digital video signal of an electronic image. It is a pre-processing circuit. Further, the digital video signal is corrected based on the pixel signal of the light shielding portion of the image sensor 27.
[0046]
The thinning / extraction processing circuit 102 performs thinning processing (processing for reducing the resolution) on the digital video signal output from the first image processing circuit 101, and the second image processing circuit 106 and the third image processing circuit. To 103. Further, the digital video signal output from the first image processing circuit 101 is extracted within the range of the AF target mark 201 shown in FIG. 4, and the extracted image data is output to the luminance detection circuit 108. To do. Note that the AF target mark 201 is an optical viewfinder in a state before continuous shooting, and is visible to the photographer from the viewfinder eyepiece 304 as shown in FIG. 4 to be described later. Used during the focal movement. The digital video signal output to the third image processing circuit 103 is a signal of an electronic subject image displayed on the LCD monitor 8 when shooting in the continuous shooting mode.
[0047]
Here, the degree of thinning of the digital video signal output to the second image processing circuit 106 is instructed by the CPU 100 according to the resolution set by the user. The degree of thinning of the digital video signal output to the third image processing circuit 103 is instructed by the CPU 100 according to the resolution suitable for image display. The thinning / extraction processing circuit 102 extracts a part of the digital video signal and outputs it to a white balance processing circuit (hereinafter referred to as WB processing circuit) 105. The CPU 100 instructs the extraction method.
[0048]
The WB processing circuit 105 outputs white balance information (WB information) for adjusting the color balance (white balance) of the image, and this WB information is sent directly to the third image processing circuit 103. Then, it is sent to the second image processing circuit 106 via the CPU 100.
[0049]
The third image processing circuit 103 is a circuit for generating an image for display on the LCD monitor 8. The digital image signal is subjected to γ correction, data bit number reduction, color adjustment based on WB information, YCbCr from RGB signals. This is a simple post-processing circuit that performs a known process such as conversion to a signal. In general, in order to repeatedly display captured images on the LCD monitor 8, the processing by software often cannot keep up with the speed. Therefore, all image processing for display is processed by the third image processing circuit 103 in hardware.
[0050]
The video decoder 104 converts the YCbCr signal of the digital video signal into an NTSC signal to form the electronic subject image, and displays the electronic subject image on the LCD 8 a of the LCD monitor 8.
[0051]
The second image processing circuit 106 is a circuit that generates the digital video signal to be stored in the flash memory 50. The second image processing circuit 106 performs γ correction, reduction of the number of data bits of the digital video signal, color adjustment based on WB information, RGB signal This is a post-processing circuit that performs known processes such as conversion from the YCbCr signal, defective pixel correction of the image sensor 27, smear correction, hue and chromaticity.
[0052]
The JPEG compression / decompression processing circuit 107 performs JPEG compression when reading the digital video signal processed by the second image processing circuit 106 in the flash memory 50, or reads out the JPEG image stored in the flash memory 50. This is a circuit for stretching.
[0053]
A luminance detection circuit 108 serving as a luminance detection unit extracts image information from a range in the AF target mark 201 which is a specific area (partial area) in the electronic image data output from the thinning / extraction processing circuit 102, An average value (average luminance level) of the output levels of each pixel corresponding to the luminance value in the screen is obtained, and the value is output to the CPU 100 as the luminance value of the subject. Note that the range within the AF target mark 201, which is the specific area, matches the distance measurement range of the focus detection device 39, which is an autofocus device, as described above.
[0054]
Next, the operation sequence of the CPU 41 will be described with reference to FIG.
FIG. 5 is a flowchart showing an imaging operation performed after the release button 303 (see FIG. 1) of the switch input means 42 is half-pressed (first release on operation) in the digital single-lens reflex camera of FIG. FIG. 6 is a flowchart showing the luminance change determination process of FIG. The flowchart in FIG. 5 is a subroutine called in the main flowchart of the CPU 41. Since the main flowchart of the CPU 41 is a conventionally known technique, the description thereof is omitted here.
[0055]
In step S1, the photometry sensor 56 is driven and controlled via the target lens 55, and photometry is performed from an area (range) defined by the AF target mark 201, which is a specific area of the electronic image shown in FIG. The luminance information of the subject is measured using the output of the sensor 56. Then, the exposure amount (the aperture amount of the aperture mechanism 22 and the shutter speed of the shutter 26) is calculated from the luminance information in accordance with a predetermined arithmetic program, and then the process proceeds to step S2.
[0056]
In step S2, the AF sensor 29 is driven and controlled via the AF sensor drive circuit 37, and the defocus amounts of the imaging lenses 21 and 23 are measured. Then, based on the distance measurement value, the focusing operation of the imaging lenses 21 and 23 is performed, and the process proceeds to step S3.
[0057]
In step S3, it is determined whether or not the camera operator has pressed down the release button of the switch input means 42 based on whether or not the second release switch is on. If the second release switch is not turned on, the process branches to step S19.
[0058]
In step S19, whether or not the camera operator has pressed the release button halfway is determined by whether or not the first release switch is on. If the first release switch is on, it is determined that the release button is half-pressed, and the process returns to step S3. On the other hand, if the first release switch is not on, it is considered that the camera operator has released his / her finger from the release button, and the process returns to the main flow as it is.
[0059]
Returning to step S3, if the second release switch is turned on, it is determined that the release button is pressed down and the process proceeds to step S4. In step S4, the movable mirror 24 is connected via the mirror drive circuit 36. Is retracted from the first position to the second position outside the imaging optical path (mirror up), and the process proceeds to step S5.
[0060]
In step S5, the continuous shooting / single shooting switching button 307 (see FIG. 1) of the switch input means 42 determines whether or not the continuous shooting mode is set. If the continuous shooting mode is set, the process proceeds to step S6.
[0061]
In step S6, the aperture operation of the aperture mechanism 22 is performed via the aperture drive circuit 35 based on the aperture amount calculated in step S1. Further, when the mode button 302 (see FIG. 1) of the switch input means 42 is used to set the Tv mode or the P mode, and after step S37 or step S36 in FIG. Based on the appropriate exposure amount correction, the aperture mechanism 22 performs the aperture operation. Thereafter, the process proceeds to step S7.
[0062]
In step S <b> 7, the CPU 41 sends a signal instructing start of continuous imaging to the signal processing circuit 45. Upon receiving this signal, the signal processing circuit 45 starts the imaging operation (integration operation) of the image sensor 27, and then proceeds to step S8.
[0063]
In step S8, the shutter 26 is opened and closed based on the shutter speed (the opening and closing time of the shutter 26) calculated in step S1. Further, here, when the mode mode 302 (see FIG. 1) of the switch input means 42 is used to set the Av mode or P mode, and after step S35 or step S36 of FIG. Based on the appropriate exposure amount correction, the shutter 26 is opened and closed. Thereafter, the process proceeds to step S9.
[0064]
In step S9, after closing the shutter 26, the signal processing circuit 45 is sent a signal instructing to stop one image pickup. Upon receiving this signal, the signal processing circuit 45 terminates the integration operation in the image sensor 27, reads out the video signal from the image sensor 27, converts it into the above-described digital video signal, and image processing associated therewith. Further, as described above, the data in the AF target mark 201 (see FIG. 4) of the digital video signal of the electronic image output from the thinning / extraction processing circuit 102 (see FIG. 3) is extracted and extracted. Processing is performed to output the processed image data to the luminance detection circuit 108, and the process proceeds to step S10.
[0065]
In step S10, the CPU 41 sends a control signal for instructing the storage and display of the digital video signal to the signal processing circuit 45. Upon receiving this signal, the signal processing circuit 45 temporarily stores the digital video signal in order in the continuous shooting data storage area of the SDRAM 48 and converts the data into a composite signal (luminance signal, color difference signal). Then, this composite signal is supplied to the LCD monitor 8, and the captured electronic subject image is displayed on the LCD 8a. Thereafter, the process proceeds to step S11.
[0066]
In step S11, luminance change determination is performed from the image data extracted from the digital video signal output from the thinning / extraction processing circuit 102 (see FIG. 3) in step S9, and the process proceeds to step S12. More specifically, as shown in FIG. 6, the luminance change circuit 108 first determines that the luminance detection circuit 108 has detected the AF target mark 201 (see FIG. 6) of the digital video signal output from the thinning / extraction processing circuit 102 in step S29. 4), the image data extracted from the inside is read, and the process proceeds to step S30.
[0067]
In step S30, the luminance detection circuit 108 extracts image information from the image data in the AF target mark 201 output from the thinning / extraction processing circuit 102, and outputs the output level of each pixel corresponding to the luminance value in the screen. The average value is obtained, and the value is output to the CPU 100 as the luminance value of the subject. Then, the process proceeds to step S31.
[0068]
In step S31, it is determined whether or not the luminance value of the output image data is the first (first) imaged value. If the brightness value is the first time, the exposure amount by the aperture mechanism 22 and the shutter 26 is appropriate, and the process branches to step S39 without determining the brightness change. In step S39, the brightness of the first image data is determined. The value is stored in the BVR1 of the internal register of the CPU 41 (see FIG. 2), and then the process returns.
[0069]
Returning to step S31, if the luminance value of the output image data is not the value captured for the first time, the process proceeds to step S32, and in step S32, the luminance value of the nth (latest) image data is set to the CPU 41. The data is stored in BVR2 of the internal register (see FIG. 2), and the process proceeds to step S33.
[0070]
In step S33, the CPU 41 calculates the difference between the absolute value of the luminance value stored in BVR2 in step S32 and the luminance value stored in BVR1 in step S39, and this absolute value difference is the EPROM 47 (see FIG. 3). It is determined whether or not the value is equal to or greater than the predetermined value α stored in. Note that, as described above, the predetermined value α indicates whether or not the latest (n-th) luminance value has changed to a value that is within the appropriate exposure range from the first (first) luminance value. This is a reference value for determination and a design value. If the difference between the absolute values is equal to or greater than the predetermined value α, the latest image data during the continuous imaging operation has a larger luminance difference than the image data captured at the beginning of the continuous imaging operation, and is inappropriate. And the process proceeds to step S34.
[0071]
In step S34, the CPU 41 determines the shooting mode set with the mode button (see FIG. 1). If the Av mode is set, the process proceeds to step S35, the Tv correction table is referred to based on the difference between BVR2 and BVR1, and the process proceeds to step S38. Alternatively, if the P mode is set, the process proceeds to step S36, the Tv correction table and the Av correction table are referred to based on the difference between BVR2 and BVR1, and the process proceeds to step S38. Alternatively, if the Tv mode is set, the process proceeds to step S37, the Av correction table is referred based on the difference between BVR2 and BVR1, and the process proceeds to step S38.
[0072]
In step S38, based on the correction value obtained in step S35, step S36, or step S37, the CPU 41 performs an exposure amount correction calculation, and then returns.
[0073]
Returning to step S33, if the difference between the absolute values is less than the predetermined value α, it is determined that the latest image data during the continuous imaging operation has not changed in luminance, and then the process returns.
[0074]
Returning to FIG. 5, in step S12, it is checked whether or not the photographer has turned off the second release switch. If it is off, it is determined that the camera operator is going to end continuous shooting, and the process proceeds to step S13. Transition. On the other hand, if not OFF, the process returns to step S6, and steps S6 to S12 are repeated until the second release switch is turned OFF. That is, if the second release switch is not turned off at this time, continuous shooting is continued regardless of the focus shift, and the electronic subject image captured immediately before is sequentially displayed in the finder 30 as a moving image. Become.
[0075]
In step S <b> 13, a signal for instructing the end of display is output to the signal processing circuit 45. Upon receiving this signal, the signal processing circuit 45 stops the display on the LCD 8a, turns off the backlight 8b, and proceeds to step S14.
[0076]
In step S14, the aperture mechanism 22 is returned from the aperture state to the open state via the aperture drive circuit 35, and the process proceeds to step S15. In step S15, the movable mirror 24 is moved to the first position via the mirror drive circuit 36. After returning to a certain imaging optical path (mirror down), the process proceeds to step S16, and in step S16, the continuous shot image temporarily stored in the SDRAM 48 as described above is sent to the flash memory 50 to the signal processing circuit 45. Instruct to store in the predetermined storage area, and then return. At this time, depending on the capacity of the captured image, it may be stored in the flash memory 50 after being JPEG compressed by the JPEG compression / decompression processing circuit 107 (see FIG. 3).
[0077]
Returning to step S5, if the continuous shooting mode is not set by the continuous / single shooting switching button 307 (see FIG. 1) of the switch input means 42, the process branches to step S21. In step S21, the single shooting mode is selected. The imaging operation at is performed. First, the diaphragm mechanism 22 is narrowed down via the diaphragm driving circuit 35 based on the diaphragm amount calculated in step S1, and the process proceeds to step S22.
[0078]
In step S22, a signal instructing to start imaging is sent to the signal processing circuit 45. Upon receiving this signal, the signal processing circuit 45 starts the imaging operation (integration operation) of the imaging device 27, and proceeds to step S23.
[0079]
In step S23, the shutter 26 is opened and closed based on the shutter speed (opening and closing time of the shutter 26) calculated in step S1, and the process proceeds to step S24.
[0080]
In step S24, after closing the shutter 26, the signal processing circuit 45 is sent a signal instructing to stop imaging. Upon receiving this signal, the signal processing circuit 45 terminates the integration operation of the image sensor 27, reads out a video signal from the image sensor 27, converts it into a digital video signal, and executes image processing associated therewith.
[0081]
In step S25, the CPU 41 sends a control signal for instructing the signal processing circuit 45 to store the digital video signal. In the single shooting mode, it is not necessary to temporarily store the digital video signal in the SDRAM 48 as in the continuous shooting mode. Therefore, the signal processing circuit 45 receives the control signal and sends the digital video signal to the predetermined flash memory 50. Is stored in the storage area. In the single shooting mode, the electronic subject image is not displayed in the viewfinder 30 as in the continuous shooting mode. Thereafter, the process proceeds to step S26.
[0082]
In step S26, the aperture mechanism 22 is returned from the aperture state to the open state via the aperture drive circuit 35, and the process proceeds to step S27. In step S27, the movable mirror 24 is moved to the first position via the mirror drive circuit 36. After returning to a certain imaging optical path (mirror down), the process proceeds to step S28.
[0083]
In step S28, it is checked whether or not the first release switch is off. If not, this check is repeated. This is to prevent the next imaging operation from being performed in the single shooting mode until the camera operator removes the finger from the release button. If it turns off, it returns to the main routine.
[0084]
As described above, in the digital single-lens reflex camera 300 showing one embodiment of the present invention, the luminance change caused by the movement of the subject during continuous imaging is continuously detected with the first luminance value immediately after the start of continuous imaging. The absolute value difference of the latest brightness value during the imaging operation is obtained, and the absolute value difference is larger than a predetermined value α that is a reference value for determining whether or not the absolute value difference has changed to a value that is within the proper exposure range. If it is larger, it is determined that the exposure amount of the captured electronic image is overexposure or underexposure, and the CPU 41 performs an exposure correction calculation, and determines the exposure amount of the imaging operation performed by the solid-state imaging device 27 to be performed subsequently. Correction was made by changing the aperture value of the aperture mechanism and / or the shutter speed of the shutter unit.
[0085]
Therefore, during continuous shooting, if the subject brightness changes to a value that is within the proper exposure range, exposure correction is automatically performed, so that it is possible to prevent a poorly exposed photo from being recorded.
[0086]
In the above embodiment, the subject brightness change during continuous shooting is detected in the AF target area. However, the detection area is not limited to this, and if there is no problem in circuit scale or processing speed, the screen A change in luminance may be detected by detecting the entire luminance distribution.
[0087]
The most common method of detecting the luminance distribution is to divide the shooting screen into a plurality of blocks and compare the first image with the latest image for each block. A method of obtaining and comparing the sum of the vertical pixel columns and the like is also effective. In other words, it is important to detect whether or not the overall brightness level of the shooting screen during continuous shooting has changed, and if this is possible, it is not a specific area in the screen such as an AF target area. It is also good.
[0088]
In this way, there is an advantage that it is possible to correct the appropriate exposure amount even when the subject deviates from the AF target area when the second and subsequent images are taken.
[0089]
【The invention's effect】
As described above, according to the present invention, it is possible to prevent the exposure amount from deviating from the appropriate exposure amount during continuous imaging, and to provide a digital single-lens reflex camera that is easy to use for photographers. it can.
[Brief description of the drawings]
FIG. 1 is a perspective view of a digital single-lens reflex camera showing an embodiment of the present invention as seen from the back side;
FIG. 2 is a block diagram showing an outline of a configuration of an electric circuit of the digital single-lens reflex camera in FIG.
3 is a block diagram showing an outline of the configuration of an electric circuit of the signal processing circuit in FIG. 2 and peripheral circuits connected thereto;
4 is a captured image diagram showing a specific region of an electronic image captured by the solid-state imaging device in FIG. 2;
FIG. 5 is a flowchart showing an imaging operation executed after half-pressing the release button of the switch input means in FIG. 2;
6 is a flowchart showing a process for determining a luminance change in FIG. 5;
[Explanation of symbols]
8. LCD monitor (display means)
8a ... LCD (display element)
24 ... Movable mirror
27 ... Solid-state imaging device (imaging means)
30 ... Finder (finder optical system)
31 ... Focus plate (finder optical system)
32 ... Pental prism (finder optical system)
33. Viewfinder eyepiece (finder optical system)
37. AF sensor drive circuit (autofocus device)
39: Focus detection device (autofocus device)
41 ... CPU (continuous imaging control means) (comparison means) (calculation means) (correction means)
56 ... Photometric sensor (photometric means)
108. Luminance detection circuit (luminance detection means)
201... AF target mark (specific area of electronic image) (ranging range)
300 ... Digital SLR camera
304 ... Finder eyepiece
α… predetermined value

Claims (7)

Imaging means for capturing a subject image and converting it into digital image data;
A metering means for metering the subject;
An arithmetic means for calculating an exposure amount at the time of an imaging operation by the imaging means based on the output of the photometry means,
Finder optics,
In the imaging optical path of the imaging means, it is at a first position for guiding the subject light beam to the finder optical system when observing the subject, and is retracted from the imaging optical path during the imaging operation by the imaging means. A movable mirror that moves to position 2,
Including a display element for displaying the digital image data converted by the imaging means, and arranged so that the image displayed on the display element can be observed by sharing a part of the observation optical path of the finder optical system Display means,
Continuous imaging control means for executing a continuous imaging operation for repeating the imaging operation by the imaging means and the image display operation by the display means while moving the movable mirror to the second position;
A luminance detecting means for detecting a luminance level of an electronic image captured by the imaging means; an initial luminance value detected by the luminance detecting means immediately after the start of continuous imaging; and a latest luminance value during the continuous imaging operation; Comparing means for determining whether or not the latest luminance value has changed from the initial luminance value;
A correction unit that corrects an exposure amount of an imaging operation performed by the imaging unit that is subsequently performed when the comparison unit determines that the latest luminance value has changed from the first luminance value;
A digital single-lens reflex camera characterized by comprising: Imaging means for capturing a subject image and converting it into digital image data;
A metering means for metering the subject;
An arithmetic means for calculating an exposure amount at the time of an imaging operation by the imaging means based on the output of the photometry means,
Finder optics,
In the imaging optical path of the imaging means, it is at a first position for guiding the subject light beam to the finder optical system when observing the subject, and is retracted from the imaging optical path during the imaging operation by the imaging means. A movable mirror that moves to position 2,
Including a display element for displaying the digital image data converted by the imaging means, and arranged so that the image displayed on the display element can be observed by sharing a part of the observation optical path of the finder optical system Display means,
Continuous imaging control means for executing a continuous imaging operation for repeating the imaging operation by the imaging means and the image display operation by the display means while moving the movable mirror to the second position;
Luminance detection means for detecting an average luminance value of a specific area in the electronic image captured by the imaging means;
The first luminance value immediately after the start of continuous imaging detected by the luminance detection means is compared with the latest luminance value during the continuous imaging operation, and the latest luminance value is more appropriate than the first luminance value. A comparison means for determining whether or not the value has changed to a value greater than
When the comparison means determines that the latest brightness value has changed beyond the first brightness value to a value that is within the appropriate exposure range, the exposure amount of the imaging operation performed by the imaging means that is subsequently performed Correction means for correcting
A digital single-lens reflex camera characterized by comprising: The digital single-lens reflex camera according to claim 1, further comprising an autofocus device, wherein a specific area in the electronic image matches a distance measurement range of the autofocus device. 3. The digital single-lens reflex camera according to claim 1, wherein the luminance detection unit outputs an average of output levels from pixels in a specific region in the electronic image. The digital single-lens reflex camera according to claim 1, wherein the correction unit changes a shutter speed and / or an aperture value according to a set shooting mode. Imaging means for capturing a subject image and converting it into digital image data;
A metering means for metering the subject;
An arithmetic means for calculating an exposure amount at the time of an imaging operation by the imaging means based on the output of the photometry means,
Finder optics,
In the imaging optical path of the imaging means, it is at a first position for guiding the subject light beam to the finder optical system when observing the subject, and is retracted from the imaging optical path during the imaging operation by the imaging means. A movable mirror that moves to position 2,
Including a display element for displaying the digital image data converted by the imaging means, and arranged so that the image displayed on the display element can be observed by sharing a part of the observation optical path of the finder optical system Display means,
Continuous imaging control means for executing a continuous imaging operation for repeating the imaging operation by the imaging means and the image display operation by the display means while moving the movable mirror to the second position;
Luminance detection means for detecting a luminance level in a part or all of the electronic image captured by the imaging means;
During the continuous imaging operation, a correction unit that corrects an exposure amount in a subsequent imaging operation according to the output of the luminance detection unit;
A digital single-lens reflex camera characterized by comprising: Imaging means for capturing a subject image and converting it into digital image data;
A metering means for metering the subject;
An arithmetic means for calculating an exposure amount at the time of an imaging operation by the imaging means based on the output of the photometry means,
Finder optics,
In the imaging optical path of the imaging means, it is at a first position for guiding the subject light beam to the finder optical system when observing the subject, and is retracted from the imaging optical path during the imaging operation by the imaging means. A movable mirror that moves to position 2,
Including a display element for displaying the digital image data converted by the imaging means, and arranged so that the image displayed on the display element can be observed by sharing a part of the observation optical path of the finder optical system Display means,
Continuous imaging control means for executing a continuous imaging operation for repeating the imaging operation by the imaging means and the image display operation by the display means while moving the movable mirror to the second position;
During the continuous imaging operation, the first electronic image captured by the imaging means is compared with the latest electronic image, and if the brightness levels of both are different, the exposure amount in the subsequent imaging operation is corrected. Correction means for
A digital single-lens reflex camera characterized by comprising:

Images