JP2004023747A - Electronic camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic camera with an increased autofocus control speed and capable of optimizing preview display at the time of autofocus control. <P>SOLUTION: A CCD imaging element 10 of a digital camera has two modes. One is a draft mode to read an image signals associated with a specified number of picture elements among all picture elements in the imaging element. The other is an autofocus mode which reads a plurality of images quickly by reading an image signal associated with a smaller number of picture elements than that of the draft mode. When a shutter button is pressed to the half-pressed state, an autofocus control is performed based on the image signal read in the autofocus mode. A display unit (LCD on the rear side) displays an image synthesized by an image Gb based on the image signal read in the draft mode immediately before transiting to the autofocus mode and an image Gh based on the image signal read in the autofocus mode. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electronic camera having an autofocus (hereinafter, also simply referred to as AF) control function and a display function of displaying an image on a liquid crystal display or the like.
[0002]
[Prior art]
A digital camera (electronic camera) generally has a display unit (display means) such as a liquid crystal display (hereinafter, also referred to as LCD). Then, on this LCD, a live view image for preview before actual shooting is updated and displayed at predetermined time intervals. Such image display for preview (hereinafter, also referred to as preview display) is very useful for grasping the photographing situation of a subject when photographing with a digital camera.
[0003]
Some digital cameras adopt a hill-climbing method using an image signal from a CCD image pickup device of the digital camera as an autofocus control method. The “hill-climbing method” is a focus control method in which the lens position at which the focus evaluation value such as the contrast of an image obtained by the CCD image pickup device is the largest is specified as the lens position in the focused state. This hill-climbing method has the advantage that it is not necessary to separately provide a distance measuring sensor for measuring the distance to the subject, and is therefore adopted in many digital cameras.
[0004]
By the way, in the CCD image pickup device, a read mode for live view (also referred to as a draft mode) for reading an image over a relatively wide range, and an image read at a higher speed by reading a part of the image in the draft mode. There is an AF reading mode (also referred to as an automatic focusing mode).
[0005]
In a digital camera having the above-described auto focus control function and display function, it is expected that the speed of the auto focus control will be increased by using such a readout mode for AF (automatic focusing mode). Is done.
[0006]
As such a technique, there is one described in JP-A-2001-318307. In this prior art, a reading mode in a CCD image pickup device is selected according to a setting as to whether or not an image is to be displayed on a display unit during photographing. Then, only when it is set that the image is not to be preview-displayed on the display unit, the image is read out in a read-out mode (corresponding to an automatic focusing mode) in which the image is read out at a relatively high speed by reading out a part of the image. On the other hand, when the preview display of the image is set on the display unit, the image is read in a read mode (corresponding to a draft mode) for reading an image over a relatively wide range, and the read image is displayed on the display unit.
[0007]
[Problems to be solved by the invention]
However, in the above-described conventional technique, when the preview display of the image is set on the display unit, the image is read out in the draft mode which is slower than the automatic focusing mode. There is a problem that can not be.
[0008]
On the other hand, even when the image is read while the image is previewed on the display unit, if the image is read in the automatic focusing mode, the preview screen display similar to the draft mode cannot be continuously updated. . This is because, in the automatic focusing mode, only an image in an area smaller than that in the draft mode is read. In order to cope with such a situation, an image immediately before the start of the autofocus control is continuously displayed on the display unit during the autofocus control, and the updating of the screen display on the display unit is stopped. However, in this case, the live view display is not updated at all during the auto focus control, and the image is stopped. Therefore, when photographing a moving subject, for example, it is not possible to confirm the position of the subject on the screen. Will occur.
[0009]
In view of the above problems, an object of the present invention is to provide an electronic camera capable of speeding up autofocus control and optimizing preview display during autofocus control.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is an electronic camera, comprising: an image pickup device for converting a subject image into an image signal by photoelectric conversion; and a display unit having a display area for displaying an image based on the image signal. And focusing control means for performing auto-focus control based on the image signal, wherein the image sensor sets a predetermined number of pixels among all pixels in the image sensor as a read mode of the image signal. A first mode for reading out a corresponding image signal; and a second mode for reading out a plurality of images at high speed by reading out image signals corresponding to a smaller number of pixels than the predetermined number of pixels among all the pixels. The focus control unit performs autofocus control based on the image signal read in the second mode, and the display unit performs autofocus control. When the second mode is selected, the combined image of the first image based on the image signal read in the first mode before the transition to the second mode and the second image based on the image signal read in the second mode is updated. It is characterized by displaying.
[0011]
According to a second aspect of the present invention, in the electronic camera according to the first aspect, the display area is divided into a first area and a second area, and the display means displays the first image in the first area. And displaying the second image in the second area.
[0012]
The invention according to claim 3 is an electronic camera, comprising: an image pickup device that converts a subject image into an image signal by photoelectric conversion; display means having a display area for displaying an image based on the image signal; Focusing control means for performing auto-focus control in the imaging device, wherein the imaging device reads out an image signal corresponding to a predetermined number of pixels among all pixels in the imaging device as the image signal reading mode. One mode, and a second mode in which a plurality of images are read out at high speed by reading out image signals corresponding to a smaller number of pixels than the predetermined number of pixels among the all pixels. Performing auto-focus control based on the image signal read in the second mode, and the display means displays the second focus when the auto-focus control is being performed. And updates displaying an enlarged image based on the image signal read out by the over-de.
[0013]
According to a fourth aspect of the present invention, there is provided an electronic camera, comprising: an image sensor for converting a subject image into an image signal by photoelectric conversion; a display unit having a display area for displaying an image based on the image signal; Focusing control means for performing auto-focus control by reading the image signal corresponding to a part of all the pixels in the image sensor as the image signal read mode. A high-speed readout mode for reading a plurality of images at a high speed, wherein the focus control unit performs autofocus control based on the image signal read in the high-speed readout mode; and the display unit performs the autofocus control. Is performed, an image based on the image signal read in the high-speed read mode is updated to a partial area in the display area. With Shimesuru, different other areas and the partial regions, and displaying the information about the shooting.
[0014]
An electronic camera according to claim 5, wherein the image pickup device converts a subject image into an image signal by photoelectric conversion, a display unit having a display area for displaying an image based on the image signal, and an electronic camera based on the image signal. Focusing control means for performing autofocus control, and input means for receiving an instruction input from an operator to perform autofocus control at high speed, the image pickup device, as the image signal read mode, A first mode for reading an image signal corresponding to a predetermined number of pixels among all pixels in the image sensor, and reading an image signal corresponding to a number of pixels smaller than the predetermined number of pixels among the all pixels A second mode for reading out a plurality of images at a high speed, and the focus control means reads out the images in the first mode when the instruction input is not input. The auto focus control is performed based on the image signal. When the instruction input is input, the auto focus control is performed based on the image signal read in the second mode. If not, the image based on the image signal read in the first mode is updated and displayed in the display area, and when the instruction input is input, the image based on the image signal read in the second mode is displayed. The display area is updated and displayed.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0016]
<1. First Embodiment>
<Schematic configuration>
1, 2 and 3 are views showing the external configuration of a digital camera 1 according to an embodiment of the present invention. FIG. 1 is a front view, FIG. 2 is a top view, and FIG. 3 is a rear view. These drawings do not always conform to the triangular projection, and the main purpose is to exemplify the appearance of the digital camera 1.
[0017]
A photographing lens 2 is provided on the front side of the digital camera 1. The photographing lens 2 has a zoom function, and is configured so that the photographing magnification can be changed by manually rotating the zoom ring 2a.
[0018]
Further, a shutter button (release button) 9 is provided on the upper surface of the digital camera 1, and the shutter button 9 is a two-stage push-in switch capable of distinguishing between a half-pressed state and a fully-pressed state by the user. When the automatic focusing mode is set, the automatic focusing control (also referred to as autofocus control) is started when the shutter button is half-pressed, and a book for photographing a recording image when the shutter button is fully pressed. Start the shooting operation.
[0019]
On the upper surface of the digital camera 1, there is provided a mode switching dial 3 for switching between "shooting mode", "reproduction mode" and "communication mode". The shooting mode is a mode in which a subject is shot to generate image data, and the shooting mode is further divided into a still image shooting mode and a moving image shooting mode. The reproduction mode is a mode in which image data recorded on the memory card 90 is reproduced and displayed on a liquid crystal display (hereinafter, referred to as LCD) 5 provided on the back side of the digital camera 1. Further, the communication mode is a mode in which data is transferred to an external computer 91 or the like via the external connection interface 38 provided on the side of the digital camera 1.
[0020]
On the rear surface of the digital camera 1, an LCD 5 for performing live view display and playback display of a recorded image and the like before an actual photographing operation, and an electronic viewfinder (hereinafter, referred to as EVF) 4 are provided. The LCD 5 and the EVF 4 each display a color image. In the following description, a case where the LCD 5 has a display pixel number of 320 × 240 is exemplified.
[0021]
Further, a menu button 6 is provided on the back of the digital camera 1, and when the menu button 6 is pressed, various menu screens are displayed on the LCD 5. Further, on the back of the digital camera 1, there is provided a control button 7 including a cross cursor button 7a for moving a display cursor on the LCD 5 in four directions and an enter button 7e provided at the center of the cross cursor button. . Using the menu button 6 and the control button 7, an operation for setting various shooting parameters is performed. The setting states of various shooting parameters are displayed on a data panel 8 arranged on the upper surface side of the digital camera 1. Various operation buttons such as an enlarge button 35a are arranged on the back of the digital camera 1 in addition to the above.
[0022]
Further, on the side of the digital camera 1, an insertion mounting portion for a memory card 90, which is a detachable recording medium, is provided, and image data obtained by actual shooting is stored in the memory card 90 set in the insertion mounting portion. Be recorded.
[0023]
<Internal configuration>
Next, the internal configuration of the digital camera 1 will be described.
[0024]
FIG. 4 is a block diagram illustrating internal functions of the digital camera 1.
[0025]
The photographing lens 2 is driven by a lens driving unit 31 and is configured to change the focus state of an image formed on the CCD image sensor 10. At the time of automatic focusing (autofocus) setting, the overall control unit 20 automatically determines the lens driving amount of the photographing lens 2 from the image, and the photographing lens 2 is driven based on this lens driving amount. At the time of manual focusing (manual focus) setting, the lens driving amount is determined according to the operation amount of the control button 7 by the user, and the photographing lens 2 is driven based on this lens driving amount.
[0026]
The CCD imaging device 10 functions as an imaging unit that captures a subject image and generates an electronic image signal, has 2560 × 1920 pixels, and has a light image of the subject formed by the imaging lens 2. (Subject image) is photoelectrically converted into an image signal of R (red), G (green), and B (blue) color components (a signal composed of a signal sequence of pixel signals received by each pixel) for each pixel. Output. The timing generator 32 generates various timing pulses for controlling the driving of the CCD imaging device 10.
[0027]
The driving method (readout mode) of the CCD imaging device 10 includes three modes: a “draft mode”, an “autofocus mode”, and a “real shooting mode”.
[0028]
The “draft mode” is a readout mode for generating an image for preview (also referred to as live view) before actual shooting. In short, the draft mode is a mode in which image signals are thinned out and read in order to generate a preview image.
[0029]
Generally, signal reading from a CCD image pickup device is performed for each horizontal line. For this reason, in the draft mode, when reading out pixel signals for each horizontal line from the CCD image pickup device 10 having 2560 pixels in the horizontal direction and 1920 pixels in the vertical direction, the CCD image pickup device 10 is driven so as to read out one line out of eight lines. You. That is, in the draft mode, the 1920 horizontal lines are read out in a state where they are thinned out by 1/8. As a result, the image G1 output from the CCD image pickup device in the draft mode has 2560 × 240 pixels as shown in FIG. The draft mode can also be expressed as a mode in which image signals corresponding to a predetermined number of pixels among all pixels in the image sensor are read.
[0030]
The “auto focus mode” (hereinafter, also referred to as AF mode) is a mode in which a plurality of images are read at high speed by reading image signals corresponding to a smaller number of pixels than in the draft mode (and the main shooting mode). is there. This automatic focusing mode is applied at the time of automatic focusing control (automatic focusing control). In the automatic focusing mode, some horizontal lines (for example, 80 lines located at the center) of the 240 lines read in the draft mode are read. As a result, the image G2 output from the CCD image pickup device in the automatic focusing mode has 2560 × 80 pixels as shown in FIGS. 6 (a) and 6 (b). The broken lines in FIGS. 6A and 6B show the image G1 in the draft mode.
[0031]
In the “autofocus mode”, image signals corresponding to a smaller number of horizontal lines than the “draft mode” (in other words, image signals corresponding to a smaller number of pixels than the “draft mode”) are read. Therefore, reading of frame images is speeded up, and a plurality of images are read at high speed. Specifically, the lines other than the 80 horizontal lines do not need to be read out as pixel signals from the CCD image sensor 10, and are discharged from the vertical transfer lines of the CCD image sensor 10 by high-speed driving using short-period drive pulses to achieve high-speed driving. , The speed of the image signal from the CCD imaging device 10 can be increased. For example, when the reading speed of the frame image in the draft mode is a maximum of 30 FPS (frames per second), the reading speed of 60 FPS is possible according to the automatic focusing mode.
[0032]
Further, the “main photographing mode” is a mode in which an image signal is read out with respect to the entire frame image, that is, all pixels of 2560 × 1920. Then, the timing generator 32 drives the CCD imaging device 10 based on the designated one of these read modes.
[0033]
An image signal obtained from the CCD image pickup device 10 is supplied to a signal processing circuit 11 (FIG. 4), and the signal processing circuit 11 performs predetermined analog signal processing on the image signal (analog signal). The signal processing circuit 11 has a correlated double sampling circuit (CDS) and an automatic gain control circuit (AGC). The signal processing circuit 11 performs noise reduction processing of the image signal by the correlated double sampling circuit, and controls the gain by the auto gain control circuit. By performing the adjustment, the level of the image signal is adjusted.
[0034]
The A / D converter 12 converts each pixel signal of the image signal into a 12-bit digital signal. The A / D converter 12 converts each pixel signal (analog signal) into a 12-bit digital signal based on an A / D conversion clock input from the overall control unit 20.
[0035]
The WB (white balance) circuit 13 performs level conversion of each of R, G, and B color components. The WB circuit 13 converts the levels of the R, G, and B color components using the level conversion table stored in the overall control unit 20. The parameters (gradients of the characteristics) of each color component of the level conversion table are set by the general control unit 20 automatically or manually for each captured image. The γ correction circuit 14 corrects the gradation of the pixel data.
[0036]
The color correction unit 15 performs color correction on the image data input from the γ correction circuit 14 based on parameters related to color correction set by the user, and converts color information expressed in the RGB color space into a YCrCb color space. Is converted to the color information represented by. By this color system conversion, a luminance component value Y is obtained for all pixels.
[0037]
The resolution conversion unit 16 performs a predetermined resolution conversion on the image data obtained from the CCD image pickup device 10 and cuts out an area.
[0038]
For example, at the time of live view display, the resolution conversion unit 16 performs predetermined resolution conversion on image data obtained by driving the CCD imaging device 10 in the draft mode, and obtains image data having an image size suitable for the number of display pixels of the LCD 5. (320 × 240 pixels) is generated. That is, at the time of live view display, the resolution conversion unit 16 performs 1/8 thinning-out only in the horizontal direction of the image G1 shown in FIG. 5 to generate a live view image Gb having 320 × 240 pixels.
[0039]
Further, at the time of automatic focusing, the resolution conversion unit 16 converts an image corresponding to an automatic focusing evaluation area (also referred to as an AF evaluation area or AF area) based on an image signal read in the “automatic focusing mode”. Generate. Specifically, the resolution conversion unit 16 extracts an image Gf corresponding to the AF evaluation area. The image Gf is extracted from the image G2 without performing the thinning process at a predetermined pixel number interval in the horizontal direction. More specifically, the image Gf of the AF evaluation area is composed of image components having 640 × 80 pixels, and as shown in FIG. 6A, the image G2 of the image G2 obtained from the CCD image pickup device 10 during automatic focusing. It is extracted by cutting out an image component of 640 × 80 pixels located at the center. The image Gf is input to the AF image memory (see FIG. 7) in the AF evaluation value calculation unit 17 and is used for calculating the AF evaluation value.
[0040]
Further, the digital camera 1 performs the live view display not only when the autofocus control (autofocus control) is not performed but also during the autofocus control. That is, the digital camera 1 performs live view display regardless of whether or not autofocus control (autofocus control) is being performed. Therefore, the resolution conversion unit 16 also generates an image Gh for live view display based on the image signal read in the automatic focusing mode for the time of the automatic focus control. Specifically, as shown in FIG. 6B, the resolution conversion unit 16 performs 1/8 thinning only in the horizontal direction of the image G2, and also generates an image Gh having 320 × 80 pixels. . Hereinafter, the live view display based on the image read in the automatic focusing mode is also referred to as “AF live view display”. In this embodiment, this AF live view display is used as a live view display during auto focus control. In addition, to distinguish from the “AF live view display”, a live view display based on only the image read in the draft mode is referred to as a “draft live view display” for convenience. In this embodiment, the “draft live view display” is used as the live view display when the auto focus control is not performed.
[0041]
Further, at the time of actual photographing, the resolution conversion unit 16 outputs the image data obtained from the color correction unit 15 to the overall control unit 20 without performing the resolution conversion process. Then, the image data obtained at the time of the main photographing is stored in the image memory 34.
[0042]
At the time of live view display, the image data subjected to the predetermined resolution conversion by the resolution conversion unit 16 is given to the display control unit 33 via the overall control unit 20, and the live view image is displayed on the LCD 5 and the EVF 4. Is performed, and is also provided to the photometry calculation unit 18 to calculate an evaluation value for automatic exposure (AE) control. On the other hand, at the time of the automatic focusing control, the image data subjected to the predetermined resolution conversion by the resolution conversion unit 16 is given to the AF evaluation value calculation unit 17 and evaluated for the autofocus control (for the automatic focusing control). A value is calculated.
[0043]
The AF evaluation value calculation section 17 functions when the shutter button 9 is half-pressed by the user, and performs an evaluation value calculation operation for performing automatic focusing control of the contrast method. Here, based on the image Gf of the AF evaluation area obtained from the resolution conversion unit 16, the sum of absolute differences between two pixels adjacent in the horizontal direction is calculated as an evaluation value for AF. The AF evaluation value calculated by the AF evaluation value calculation unit 17 is output to the overall control unit 20.
[0044]
The photometry operation unit 18 divides the image data of 320 × 240 pixels output from the resolution conversion unit 16 in the draft mode into, for example, 300 (20 × 15) blocks, and evaluates the AE evaluation value based on the representative luminance value of each block. Is calculated. The AE evaluation value calculated by the photometry calculation unit 18 is output to the overall control unit 20.
[0045]
The image memory 34 is a memory for temporarily storing image data obtained by the CCD image pickup device 10 and subjected to the above-described image processing. The image memory 34 has a storage capacity of at least one frame. When a recording instruction is given by the user, the image data is transferred from the image memory 34 to the memory card 90, and the image data is recorded and stored.
[0046]
The card interface (card I / F) 37 is an interface for writing and reading image data to and from the memory card 90 mounted on the insertion mounting section on the side of the digital camera 1. When reading / writing image data from / to the memory card 90, the compression / expansion unit 36 performs a compression process or an expansion process on the image data by, for example, the JPEG method. An external connection interface (external connection I / F) 38 is an interface for enabling communication with an external computer 91 via a communication cable or the like, and is realized by, for example, a communication interface conforming to the USB standard. Via the card I / F 37 and the external connection I / F 38, a control program recorded on a recording medium such as a CD-ROM set in the memory card 90 or the external computer 91 is stored in the RAM 20a or the ROM 20b of the overall control unit 20. Can be captured.
[0047]
The operation unit 35 is an operation unit including the mode switching dial 3, the menu button 6, the control button 7, the shutter button 9, the enlargement button 35a, and the like, and is a member for the user to operate the settings of the digital camera 1.
[0048]
The overall control unit 20 is configured by a microcomputer including a RAM 20a and a ROM 20b therein. The microcomputer executes a predetermined program, and functions as a control unit that controls the above units in an integrated manner.
[0049]
The overall control unit 20 has different functions when the digital camera 1 is in the shooting mode and when the digital camera 1 is in the playback mode.
[0050]
In the photographing mode, the overall control unit 20 instructs a timing generator to drive the CCD imaging device 10 to the timing generator. Specifically, the CCD image sensor 10 is set to the draft mode during live view display (more precisely, “draft live view display”), and the CCD image sensor 10 is set to the automatic focus mode during automatic focusing (AF). At the time of the main photographing operation, the CCD image pickup device 10 is set to the main photographing mode.
[0051]
FIG. 7 is a block diagram showing main functions of the digital camera 1 at the time of live view display in the shooting mode. The cursor position detection unit 51 and the readout area control unit 52 are processing units that perform predetermined functions when a microcomputer executes a predetermined program, and perform a part of a plurality of functions of the overall control unit 20. It is responsible. FIG. 7 also shows detailed functional blocks in the display control unit 33. The display control unit 33 displays a live view image on the LCD 5 (or the EVF 4) by cooperating with the overall control unit 20. The functions of the cursor position detection unit 51, the read area control unit 52, and the display control unit 33 will be described later.
[0052]
<Display overview>
Next, an outline of a display state during the autofocus control will be described.
[0053]
FIG. 8 is a diagram showing a display screen of the LCD 5 during the autofocus control. As shown in FIG. 8, the entire display area of the LCD 5 is divided into a central band area BC and a peripheral area. The peripheral region is further divided into an upper band-shaped region BU and a lower band-shaped region BL. The upper band-shaped region BU and the lower band-shaped region BL are regions provided above and below the center band-shaped region BC of the LCD 5, respectively.
[0054]
Then, at the time of the auto focus control, the auto focus control is performed based on the image signal read from the CCD imaging device 10 in the auto focus mode, and based on the image signal read in the auto focus mode. Live view display is performed on the LCD 5. More specifically, at the time of autofocus control, as shown in FIG. 8, an image (also referred to as an “updated image”) Gh read in the automatic focusing mode is displayed in the central band-like area BC of the LCD 5. In the upper band-shaped area BU and the lower band-shaped area BL, an image (also referred to as a “non-updated image”) Gb that has been read out in the draft mode before (here, immediately before) the shift to the automatic focusing mode is displayed. You. Thus, on the LCD 5, the updated image Gh and the non-updated image Gb are combined and displayed. Further, the image Gh and the image Gb are combined and displayed so that the magnification of the subject image becomes the same (in other words, the subjects having the same size in the real space have the same size on the screen).
[0055]
As shown in FIG. 7, the display control unit 33 includes a display image processing unit 41, a display image processing unit 42, a display image synthesizing unit 43, a VRAM 44, and a switching unit 45. A simple display control operation is realized.
[0056]
The display image processing unit 41 and the display image processing unit 42 are processing units that perform predetermined image processing on an input image. More specifically, the display image processing unit 41 is a processing unit that performs predetermined image processing (for example, blur processing, luminance adjustment processing, reduction processing, and the like) on the non-updated image Gb stored in the image memory 34. is there. Further, the display image processing unit 42 is a processing unit that performs predetermined image processing (for example, enlargement processing or the like) on the updated image Gh output from the resolution conversion unit 16.
[0057]
The display image synthesizing unit 43 is a processing unit that synthesizes an image output from the display image processing unit 41 and an image output from the display image processing unit 42 to generate a predetermined image.
[0058]
Further, the VRAM 44 is an image memory for video output, and temporarily stores the synthesized image output from the display image synthesis unit 43.
[0059]
Further, the switching unit 45 has a function of selecting a display unit of an output destination, and an image from the VRAM 44 is output to the selected display unit. The switching unit 45 outputs an image in the VRAM 44 to one of the LCD 5 and the EVF 4 or both the LCD 5 and the EVF 4. In the following description, a case where the present invention is applied to an image output to the LCD 5 will be mainly described. However, the present invention may be applied to an image output to the EVF 4.
[0060]
Such display control enables display output in a mode as shown in FIG. The detailed operation of each unit will be described later.
[0061]
<Detailed operation>
Next, this display operation will be described in more detail.
[0062]
Here, when the shutter button 9 is half-pressed (also referred to as state S1), an image is read out from the CCD image sensor 10 in the automatic focusing mode to perform autofocus control, and the above-described composite display (FIG. 8) (See AF live view display) will be described.
[0063]
FIG. 9 is a timing chart showing the operation of the digital camera 1, and FIG. 10 is a conceptual diagram showing an operation of reading from the CCD image sensor 10.
[0064]
As shown in FIG. 9, after the exposure operation is performed, the CCD image sensor 10 delays one cycle (here, 1/30 second or 1/60 second) of each pixel in the CCD image sensor 10. The stored charge is read as an image signal. This read operation is performed according to the command pulses VD and VT.
[0065]
Here, the command pulse VD is a pulse for instructing all the photodiodes in the CCD image sensor 10 to output the respective accumulated charges to the vertical register in the CCD image sensor 10. The command pulse VT is a pulse for commanding a vertical transfer register in the CCD 10 to transfer. An image signal corresponding to each horizontal line is output by repeatedly sending the command pulse VT at a fixed minute cycle. Specifically, an image signal corresponding to each horizontal line from the upper side to the lower side is transmitted according to each command pulse VT.
[0066]
As shown in FIG. 10, in the draft mode, an image signal including 240 horizontal lines is read according to the command pulses VD and VT. The image signal read in the draft mode corresponds to the image G1. On the other hand, in the automatic focusing mode, an image signal including 80 horizontal lines is read according to the command pulses VD and VT. The image signal read in the automatic focusing mode corresponds to the image G2.
[0067]
Further, when the reading mode of the CCD imaging device 10 is changed from the draft mode to the automatic focusing mode, the reading interval is shortened, and high-speed reading becomes possible. This is because, in the draft mode, 240 horizontal lines are read out, whereas in the automatic focusing mode, 80 horizontal lines need to be read out. More specifically, in the automatic focusing mode, after the image signal of the pixel corresponding to the upper band-shaped area BU is read at high speed, the image signal of the pixel corresponding to the central band-shaped area BC is read at normal speed. Then, the image signal of the pixel corresponding to the lower band-shaped area BL is read out at high speed. By reducing the number of pixels read at a normal speed, the speed of reading pixels can be increased. In FIG. 10, portions denoted by symbols W1 and W2 indicate portions that perform an operation of reading unnecessary image signals at high speed.
[0068]
Hereinafter, with reference to FIG. 9, the photographing operation of the digital camera 1 will be described while roughly distinguishing into five periods T1, T2, T3, T4, and T5.
[0069]
When the “photographing mode” is selected by operating the mode switching dial 3, a live view display (draft live view display) is performed on a predetermined display unit (the LCD 5 in this case) in the period T1. During this period T1, the auto focus control has not been performed yet.
[0070]
Then, in this period T1, an image signal is read from the CCD image sensor 10 in the draft mode. Specifically, an image signal corresponding to an image G1 (FIG. 5) having a pixel size of 2560 × 240 is read from the CCD imaging device 10. Then, an image Gb for a live view having a pixel size of 320 × 240 generated by the resolution converter 16 or the like based on the image signal is displayed on the LCD 5.
[0071]
More specifically, as shown in FIG. 7, the live view image Gb generated by the resolution conversion unit 16 is temporarily stored in the image memory 34, and thereafter, the display image processing unit 41, the display image synthesis unit 43, It is displayed on the LCD 5 via the VRAM 44 and the switching unit 45. Here, the image Gb is not subjected to any special processing by the display image processing unit 41 and the display image synthesizing unit 43, and passes through these processing units 41 and 42 as they are. Further, the switching unit 45 selects the LCD 5 as the display unit of the output destination. Thereby, the image Gb is displayed on the LCD 5 as a live view image. In the live view display (draft live view display) during this period T1, the display image is updated at a speed of 30 FPS.
[0072]
Thereafter, when the shutter button 9 is pressed down to the half-pressed state S1 by the operator, the reading mode of the CCD image pickup device 10 is changed to the automatic focusing mode in the period T2. Specifically, the read area control section 52 of the overall control section 20 controls the timing generator 32 to read image signals from the CCD image sensor 10 in the automatic focusing mode. During this period T2, auto focus control is performed and live view display (AF live view display) is performed.
[0073]
In this period T2, an image signal is read from the CCD image sensor 10 in the automatic focusing mode. Specifically, an image signal corresponding to an image G2 (FIGS. 6A and 6B) having a pixel size of 2560 × 80 is read from the CCD imaging device 10. Then, the resolution conversion unit 16 generates an image Gf of the AF evaluation area having a pixel size of 640 × 80 based on the image signal. The resolution conversion unit 16 also generates an image Gh having a pixel size of 320 × 80 by performing 1/8 thinning in the horizontal direction based on an image signal having a size of 2560 × 80.
[0074]
The AF evaluation value calculation unit 17 calculates an AF evaluation value based on the pixel value of each pixel in the image Gf in the AF evaluation area. Then, auto focus control is performed based on the AF evaluation value. As a control method, a so-called “hill climbing method” is adopted. In the “hill-climbing method”, an AF evaluation value (contrast value of an image, etc.) for each lens position is calculated while driving a lens, a lens position P at which the AF evaluation value is maximized is determined, and a photographing lens is set at the lens position P. 2 is a control method in which the subject is brought into a focused state by moving the object 2. During this autofocus control, an image signal is read from the CCD image sensor 10 at a high frame rate (here, at 60 FPS) in the autofocus mode, so that the autofocus control can be speeded up.
[0075]
Further, as shown in FIG. 8, the image Gh is combined with the image Gb and displayed on the LCD 5. Specifically, the image Gb acquired in the draft mode at the end of the period T1 remains in the image memory 34 (FIG. 7) without being updated after the transition to the period T2, and the display image processing unit 41 Is input to the display image synthesizing unit 43 via the. The image Gh from the AF evaluation value calculation unit 17 is updated at a high frame rate (here, at 60 FPS), and is input to the display image synthesis unit 43 via the display image processing unit 42. Here, in the display image processing unit 41 and the display image processing unit 42, the image data passes without any special processing. The display image combining unit 43 generates a combined image of the image Gh and the image Gb, and transfers the combined image to the VRAM 44. The image data of the VRAM 44 is output to the LCD 5 selected by the switching unit 45. By repeating such an operation at an arbitrary cycle, a composite image as shown in FIG.
[0076]
In the live view display (AF live view display) during this period T2, the display image (composite image) is updated at a frame rate of 60 FPS. However, it is not necessary to update at such a high frame rate, and the image display may be updated in the period T2 at the same frame rate (30 FPS) as the period T1.
[0077]
When the subject is brought into focus by the autofocus control operation in the period T2, the autofocus control ends, and the mode returns to the draft mode in the period T3. In this period T3, the same operation as in the period T1 is performed.
[0078]
Thereafter, when the shutter button 9 is pressed down to the fully pressed state S2 by the operator, the reading mode of the CCD imaging device 10 is changed to the main shooting mode in the period T4. Specifically, the readout area control unit 52 of the overall control unit 20 controls the timing generator 32 to read out the image signal from the CCD image pickup device 10 in the main shooting mode.
[0079]
In this period T4, after an exposure operation for a time corresponding to a predetermined shutter speed (for example, 1/15 second), an image signal is read from the CCD image sensor 10 in the main photographing mode. Specifically, an image signal corresponding to a pixel size of 2560 × 1920, that is, an image signal of the size of the entire frame is read. Further, when predetermined image processing such as compression processing is performed on the obtained image signal, an image file in a predetermined format is generated as image data. The generated image file is recorded on the memory card 90. In addition, at the time of the main shooting, the live view display is temporarily interrupted.
[0080]
When the recording operation on the memory card 90 is completed, the mode returns to the draft mode again in the period T5. In this period T3, the same operation as in the period T1 is performed. Thereafter, the same operation is repeated.
[0081]
As described above, according to the digital camera of the first embodiment, at the time of the autofocus control, the reading from the CCD image pickup device 10 is performed in the automatic focusing mode. Can be. Also, as shown in FIG. 8, the updated image Gh is displayed in the band-shaped area BC even during the auto focus control, and the latest image relating to the subject is displayed on the LCD 5. That is, a situation in which an image is not updated at all during autofocus control can be avoided. Furthermore, since the non-updated image Gb is displayed in the upper band-shaped region BU and the lower band-shaped region BL, the position of the updated image Gh in the composite image of the non-updated image Gb and the updated image Gh can be confirmed. Therefore, the operator can more surely confirm the subject (confirm the in-focus state and / or confirm the composition).
[0082]
<AF live view display when focus position is changed>
Further, in the digital camera 1, it is possible to change a “focus position” which is a predetermined point in the AF area in the auto focus control according to an input from an operator. Next, the display mode of the live view display when the focus position is changed will be described.
[0083]
Specifically, in the shooting mode, the focus position is designated as shown in FIG. 11 by pressing the enter button 7e (FIG. 3) of the control button 7 for a predetermined period (for example, one second) by the operator. A cursor CR (focus position designation display) is displayed on the LCD 5. Therefore, the display image synthesizing unit 43 uses the position information Dc (FIG. 7) stored in the cursor position detecting unit 51 to superimpose and display a cross-shaped figure indicating the cursor CR on the display screen.
[0084]
Thereafter, the operator can move the displayed cursor CR in each of the up, down, left, and right directions by operating the cross cursor button 7a of the control button 7. This allows the operator to move the cursor CR to a desired position on the screen to change the focus position and select a subject to be subjected to the automatic focus operation.
[0085]
At this time, the arrangement of the band-shaped area BC where the updated image is displayed is also changed according to the position of the cursor CR. For example, in FIG. 8, of the 240 horizontal lines, a screen composed of 80 horizontal lines (see FIG. 6 (b)) existing from the 81st to the 160th in the vertical direction is located at the center. It is displayed in the band-like area BC. On the other hand, in FIG. 11, the cursor CR has been moved upward by １ ／ of the vertical length of the screen. Then, in accordance with the position of the cursor CR after this movement, the position of the horizontal line read from the CCD image sensor 10 also moves upward. Specifically, of the 240 horizontal lines, a screen composed of 80 horizontal lines existing from the 41st to the 120th in the vertical direction is read out from the CCD imaging device 10 in the automatic focusing mode. , The resolution in the horizontal direction is corrected and displayed in the band area BC.
[0086]
Such an operation is realized by the cursor position detection unit 51 and the read area control unit 52. Specifically, the cursor position detection unit 51 detects the position of the cursor CR, and the read area control unit 52 changes the position of the partial area to be read in the automatic focusing mode according to the position of the cursor CR. The read area control unit 52 changes the position of the horizontal line to be read, and then drives the CCD image sensor 10 so that an image signal corresponding to the horizontal line to be read is read.
[0087]
When the operator finishes the movement instruction of the cursor CR, the display of the cursor CR is erased from the screen by pressing the determination button 7e (FIG. 3) of the control button 7 again for a predetermined period (for example, one second). it can. The position of the cursor CR is stored by the cursor position detection unit 51, and the subsequent autofocus control is performed according to the position of the cursor CR.
[0088]
Referring back to FIG. When the position of the central band-shaped area BC is changed by moving the cursor CR, the ratio between the number of horizontal lines corresponding to the upper band-shaped area BU and the number of horizontal lines corresponding to the lower band-shaped area BL is changed. The point is different from the previous state. FIG. 10 shows the relationship between the widths of the two parts W1 and W2 such that W1 = W2 before the cursor is moved, but W1 <W2 after the cursor CR is moved.
[0089]
However, the total number of readout horizontal lines in the upper band-shaped area BU and the lower band-shaped area BL remains unchanged before and after the change, and is 160 lines. Therefore, the image signals of the same number (160) of horizontal lines as before the change are read out at high speed, and only the image signals of the pixels corresponding to the central band area BC are read out at normal speed.
[0090]
As described above, since the position of the AF area can be designated by the cursor CR, more flexible autofocus control can be performed. Further, the arrangement of the central band-shaped area BC in the display area of the LCD 5 is changed according to the position of the AF area, so that more flexible display is possible on the LCD 5.
[0091]
The operation of moving the focus position using the cursor CR may be performed before the shutter button 9 is set to the half-pressed state S1 in the period T1, or the shutter button 9 is set to the half-pressed state S1. May be performed in a period T2 after the above. FIG. 10 assumes a case where the focus position is moved by the cursor CR in a period T2 after the shutter button 9 is half-pressed to the state S1.
[0092]
<Modification of First Embodiment>
In the first embodiment, in the live view display at the time of autofocus control, a case where the updated image Gh is displayed in the center band region BC and the non-updated image Gb is displayed in the upper band region BU and the lower band region BL. Was exemplified. However, when photographing a rapidly moving subject while moving the digital camera 1, a discontinuous portion occurs at the boundary between the image Gh that is updated as needed and the image Gb that is not updated. If no processing is performed, the discontinuous portion may give an unnatural impression to the operator.
[0093]
In contrast, by specifying the updated portion and the non-updated portion, this unnaturalness can be reduced. For example, as shown in FIG. 12, the non-updated portion is specified by reducing the luminance of the non-updated image Gb to a predetermined ratio (such as 1/2) as compared with the updated image Gh. Then, the image Gh is updated and displayed at normal luminance only in the central band-shaped area BC as needed, thereby clearly indicating that the band-shaped area BC is an updated portion. Thereby, the operator can easily recognize that the low luminance portion is the non-updated portion and the normal luminance portion is the updated portion.
[0094]
Alternatively, as shown in FIG. 13, the non-updated image Gb is subjected to the blurring process to clearly indicate the non-updated portion, and the image Gh in the normal state where the blurring process has not been performed is occasionally performed only in the central band-shaped area BC. The updated portion may be specified by updating and displaying the updated portion. Thus, the operator can easily recognize that the portion subjected to the blurring process is the non-updated portion and the normal portion (the portion not subjected to the blurring process) is the updated portion.
[0095]
Further, as shown in FIG. 14, the updated image Gh is displayed in the central band-shaped area BC while being updated as needed, and a predetermined color is displayed in the upper band-shaped area BU or the lower band-shaped area BL (here, the lower band-shaped area BL). A reduced image of the non-updated image Gb may be displayed together with the background image. In the reduced image in FIG. 14, the position of the updated image Gh in the reduced image and the rectangle LR indicating the position of the AF area are also clearly shown.
[0096]
The brightness reduction processing, the blur processing, the reduction processing, and the like are realized by the display image processing unit 41. Specifically, the display image processing unit 41 (FIG. 7) performs predetermined image processing (“brightness change processing”, “blur processing”, or “reduction”) on the non-updated image Gb stored in the image memory 34. And the like, and inputting the processed image to the display image synthesizing unit 43.
[0097]
Specifically, when generating the image in FIG. 12, the display image processing unit 41 performs a luminance change process on the image Gb to generate a processed image, and the display image combining unit 43 generates the processed image and the image. And Gh.
[0098]
In generating the image in FIG. 13, the display image processing unit 41 performs a blurring process on the image Gb to generate a processed image, and the display image synthesis unit 43 synthesizes the processed image and the image Gh. do it.
[0099]
Further, in generating the image in FIG. 14, the display image processing unit 41 performs a reduction process on the image Gb, and performs a boundary between the band-shaped region BC and other regions (upper band-shaped region BU and lower band-shaped region BL). , And a rectangle LR indicating the position of the AF area is generated in the reduced image to generate a processed image RP. Then, the display image combining unit 43 combines the background image (such as a blue-back image) BB of the predetermined color, the processed image RP, and the image Gh. Note that an image stored in the ROM 20b may be used as the background image BB.
[0100]
<2. Second Embodiment>
The second embodiment is a modification of the first embodiment, and the digital camera of the second embodiment has the same configuration and the like as the digital camera of the first embodiment. The following description focuses on the differences.
[0101]
In the first embodiment, an example has been described in which a composite image of the image Gh read in the automatic focusing mode and the image Gb that has been obtained at a time before that is displayed. On the other hand, in the second embodiment, as shown in FIG. 15, while the updated image Gh is displayed in the central band-shaped area BC in the same manner as in the first embodiment, photographing is performed in the lower band-shaped area BL. An example in which an image (Gr, Gm) expressing information on the display is displayed will be described. Further, a predetermined background image BB is displayed in a blank area of the upper band-shaped area BU and the lower band-shaped area BL. As described above, on the display screen (display area) of the LCD 5, a composite image of the image Gh, the images Gr, Gm, and the background image BB is displayed.
[0102]
Here, examples of the image expressing the information regarding the photographing include an image Gr expressing the information regarding the setting of the digital camera 1 and the image Gm expressing the information regarding the evaluation value for the auto focus control. Here, in the image Gr, information Dr relating to settings of the digital camera 1 such as a shutter speed, an aperture value, a focal length, and a white balance is described as character information. Further, the image Gm shows information Dm relating to the evaluation value for autofocus control as a horizontal bar graph, and the length of the bar portion of the horizontal bar graph changes with a change in the evaluation value for autofocus control. The operator can recognize how close to the focused state is based on the length of the rod portion.
[0103]
More specifically, the information Dr is input from the overall control unit 20 to the display image synthesis unit 43, and the information Dm is input from the AF evaluation value calculation unit 17 to the display image synthesis unit 43. Then, the display image synthesizing unit 43 generates a synthesized image obtained by synthesizing the images Gr and Gm, the image Gh, and the background image BB based on the information Dr and Dm. By displaying such a composite image repeatedly at a predetermined cycle, the latest image of the subject can be updated and displayed on the LCD 5.
[0104]
Further, as described above, the AF cursor CR may be moved. In that case, it is preferable to change the arrangement of the information on the photographing according to the position of the cursor CR. For example, as shown in FIG. 16, when the central band-shaped area BC exists below FIG. 15, the information related to imaging is divided into two, and the information divided into one is divided into the upper band-shaped area BU. The displayed image may be displayed, and an image expressing the information divided into the other may be displayed in the lower band-shaped area BL. More specifically, in the upper band-shaped area BU, an image Gr1 in which setting information on the shutter speed, the aperture value, and the focal length is described as characters is displayed. Is displayed.
[0105]
As described above, according to the digital camera of the second embodiment, at the time of autofocus control, reading from the CCD image pickup device 10 is performed in the automatic focusing mode, so that the speed of the autofocus control can be increased. it can. Also, as shown in FIG. 15 and the like, the updated image Gh is displayed in the band area BC even during the auto focus control, and the latest image of the subject is displayed on the LCD 5. That is, a situation in which an image is not updated at all during autofocus control can be avoided. Therefore, the operator can confirm the subject more reliably. In addition, since the information regarding the shooting is displayed on the display screen, the operator can also check the information regarding the shooting.
[0106]
<3. Third embodiment>
The third embodiment is a modification of the first embodiment, and the digital camera of the third embodiment has the same configuration as the digital camera of the first embodiment. The following description focuses on the differences.
[0107]
In the first embodiment, an example has been described in which the updated image Gh is displayed in the central band-shaped area BC, and the non-updated image Gb is displayed in the upper band-shaped area BU and the lower band-shaped area BL. On the other hand, in the third embodiment, a case where the update image Gh is enlarged and displayed over the entire screen will be exemplified.
[0108]
Also in the third embodiment, a case where the auto focus control is started in response to the shutter button 9 being set to the half-pressed state S1 will be exemplified. In the third embodiment, the image Gh based on the image signal read from the CCD image sensor 10 in the automatic focusing mode is enlarged and displayed over the entire screen at the same time as the start of the autofocus control.
[0109]
FIG. 17 is a diagram showing a display screen of the LCD 5 before the shutter button 9 is pressed. On this display screen, an image Gb based on an image signal read in the draft mode is displayed together with a cursor CR, a rectangle LR indicating an AF area, and boundary lines LU and LL.
[0110]
FIG. 18 is a diagram showing a display screen while the shutter button 9 is half-pressed and the autofocus control is being executed.
[0111]
As shown in FIG. 18, during the autofocus control, an image Gk based on the image signal read in the automatic focusing mode is enlarged and displayed over the entire screen. More specifically, as shown in FIG. 7, the resolution conversion unit 16 determines the pixel size of 640 × 80 based on the image signal of 2560 × 80 read out from the CCD image pickup device 10 in the automatic focusing mode. An image Gf of the AF evaluation area having the following is generated. This image Gf is input to the AF evaluation value calculation unit 17 and used for evaluation value calculation and the like in the autofocus control, and is further output to the display image processing unit 42.
[0112]
Then, the display image processing unit 42 performs a resolution conversion process on the image Gf having a pixel size of 640 × 80, and generates an image Gk having a pixel size of 320 × 240. Then, the image Gk is displayed over the entire screen of the LCD 5. As a result, the image within the rectangle LR indicating the AF area in FIG. Note that the image Gk corresponds to an image obtained by enlarging a part of the image Gb in FIG. 17, and thus can be expressed as an “enlarged image”. In addition, the resolution conversion processing for generating such an enlarged image can be regarded as “enlargement processing” because the vertical size is increased from 80 to 240 for enlarged display.
[0113]
On the other hand, the image Gb is subjected to a reduction process by the display image processing unit 41. The image Gb is an image read out in the draft mode immediately before switching to the automatic focusing mode and stored in the image memory 34. The scaling ratio (reduction ratio) in the reduction process is preferably such a value that the reduced image Gb is small enough not to disturb the enlarged image Gk and large enough to confirm the composition of the subject. (For example, 1/3).
[0114]
Then, the enlarged image Gk and the reduced image Gb are combined by the display image combining unit 43, transferred to the VRAM 44, and output to the LCD 5 selected by the switching unit 45. As a result, a screen as shown in FIG. 18 is displayed on the LCD 5. By displaying such an image repeatedly at an arbitrary cycle, the latest image (enlarged image) of the subject can be updated and displayed on the LCD 5.
[0115]
In the third embodiment, since the image Gk is displayed and the normal size image Gh is not displayed, it is sufficient to generate the image Gk using the image Gf read and generated in the automatic focusing mode. Therefore, there is no need to generate an image Gh having a pixel size of 320 × 80 as in the other embodiments.
[0116]
As described above, according to the digital camera 1 of the third embodiment, at the time of the autofocus control, the reading from the CCD image pickup device 10 is performed in the automatic focusing mode, so that the speed of the autofocus control is increased. Can be. The updated image is displayed on the LCD 5 even during the auto focus control, and the latest image of the subject is displayed on the LCD 5. That is, it is possible to avoid a situation in which an image is not updated at all during the autofocus control. Therefore, the operator can confirm the subject more reliably. In addition, the subject to be focused in the AF area is displayed in an enlarged manner, so that the operator can more surely confirm the subject and the like.
[0117]
<4. Other modified examples>
<Type of autofocus control start instruction>
In each of the above embodiments, the case where the autofocus control is performed only when the shutter button 9 is pressed down to the half-pressed state S1 has been described. However, the autofocus control may be performed at another time. For example, in the “photographing mode”, autofocus control may be always performed. Further, in the “photographing mode”, in addition to performing relatively low-speed autofocus control, when the shutter button 9 is pressed down to the half-pressed state S1, relatively high-speed autofocus control is performed. You may do so. Hereinafter, such modified examples will be described.
[0118]
Specifically, until the shutter button 9 is half-pressed, the image signal from the CCD image sensor 10 is read out in the "draft mode" to obtain the AF evaluation value. The read frame rate in the draft mode is 30 FPS. On the other hand, after the shutter button 9 is set to the half-pressed state S1, the image signal from the CCD image sensor 10 is read out in the "automatic focusing mode" to obtain the AF evaluation value. The read frame rate in the automatic focusing mode is 60 FPS.
[0119]
FIG. 19 is a timing chart when an image read in the draft mode is used for live view display. In FIG. 19, the image signal is continuously read out from the CCD image pickup device 10 in the draft mode and the AF evaluation value is obtained when the auto focus control is executed or not, and the auto focus control is executed. Done.
[0120]
On the other hand, when the shutter button 9 is in the half-pressed state S1, an operation as shown in FIG. 9 is performed. That is, the reading mode from the CCD imaging device 10 is changed from the draft mode to the automatic focusing mode, the AF evaluation value is obtained using the image of the AF area that is updated at a high speed in the automatic focusing mode, and the automatic focusing control is performed. Is
[0121]
Here, the shutter button 9 functions as an input unit that receives an instruction input from an operator indicating that autofocus control should be performed at high speed. By pressing the shutter button 9 to the half-pressed state S <b> 1, the operator can give the digital camera 1 an instruction input indicating that the autofocus control should be performed at high speed.
[0122]
Further, when the instruction input is input, the AF evaluation value calculation unit 17 performs autofocus control based on the image signal read in the automatic focusing mode. When the instruction input is not input, the AF evaluation value calculation unit 17 operates in the draft mode. Autofocus control is performed based on the read image signal.
[0123]
Further, when the instruction input is input, a composite image of the image Gh based on the image signal read in the automatic focusing mode and the image Gb already obtained at a time before that is displayed on the LCD 5. When the instruction input is not input, the image Gb based on the image signal read in the draft mode is displayed on the LCD 5.
[0124]
As a result, when the instruction input of the operator is not input, the normal speed auto focus control is performed and the normal live view display is performed. On the other hand, when an instruction input from the operator is input, the auto focus control is performed at a relatively high speed, and the live view display using the image based on the image signal read in the automatic focusing mode is performed. Is As the latter live view display, for example, each of the display modes shown in FIGS. 8, 15, and 18 can be used.
[0125]
According to such an operation, when the above-mentioned instruction input is given by pressing the shutter button 9, the auto focus control is performed using the image signal read out at a high speed in the automatic focusing mode. The control speed increases.
[0126]
In addition, since the updated image can always be displayed on the display unit during the auto focus control, it is possible to avoid a situation in which the image is not updated at all during the auto focus control, and the operator can confirm the subject more easily. It can be performed reliably.
[0127]
Further, since the level of the autofocus control speed is changed according to the presence or absence of an instruction from the operator, it is possible to reduce an uncomfortable feeling of the operator due to a change in the display state during the autofocus control. This is because switching from normal live view display to live view display using an image in the automatic focusing mode is performed only when an instruction is input from the operator. That is, since the operator can predict a change in the display state, it is possible to reduce an uncomfortable feeling of the operator due to the change in the display state.
[0128]
<Others>
In the above embodiment, the case where the reading mode from the CCD image pickup device 10 is set to the draft mode when the auto focus control is not performed in the photographing mode has been described, but the invention is not limited to this. For example, when the autofocus control is not performed in the photographing mode, the reading mode from the CCD imaging device 10 may be set to the main photographing mode.
[0129]
The specific embodiments described above include inventions having the following configurations.
[0130]
(1) In the electronic camera according to claim 2,
Input means for receiving a designation input for designating the position of the AF area;
Further comprising
The arrangement of the second area in the display area is changed according to the position of the AF area.
[0131]
(2) In the electronic camera according to claim 1,
The electronic camera according to claim 1, wherein the first image is displayed with lower luminance than the second image.
[0132]
(3) In the electronic camera according to claim 1,
An electronic camera, wherein the first image is displayed after being subjected to a blurring process.
[0133]
(4) In the electronic camera according to claim 1,
An electronic camera, wherein the first image is displayed in a reduced size.
[0134]
(5) In the electronic camera according to claim 3,
When the autofocus control is being performed, the display unit combines the reduced image of the image based on the image signal read in the first mode and the enlarged image before shifting to the second mode. An electronic camera characterized by displaying an image.
[0135]
(6) In the electronic camera according to claim 4,
The electronic camera according to claim 1, wherein the information on the photographing is information on an evaluation value used for autofocus control.
[0136]
(7) In the electronic camera according to claim 4,
The electronic camera according to claim 1, wherein the information on the photographing is information on settings of the electronic camera.
[0137]
(8) In the electronic camera according to claim 4,
Input means for receiving a designation input for designating the position of the AF area;
Further comprising
The position of the partial area in the display area is changed according to the position of the designated AF area,
The electronic camera according to claim 1, wherein an arrangement of the information regarding the imaging is changed according to a position of the partial area.
[0138]
【The invention's effect】
As described above, according to the first and second aspects of the present invention, the focus control unit performs the auto focus control based on the image signal read in the second mode. Higher speed can be achieved. Further, when the autofocus control is being performed, the display unit outputs the first image based on the image signal read in the first mode before shifting to the second mode and the image signal read in the second mode. Since the composite image with the second image based on the updated image is updated and displayed, it is possible to avoid a situation in which the image is not updated at all during the autofocus control. Therefore, the operator can more surely confirm the subject.
[0139]
According to the third aspect of the present invention, since the focus control unit performs the auto focus control based on the image signal read in the second mode, the speed of the auto focus control can be increased. Further, the display means updates and displays the enlarged image based on the image signal read in the second mode when the autofocus control is being performed, thereby avoiding a situation in which the image is not updated at all during the autofocus control. can do. Therefore, the operator can more surely confirm the subject.
[0140]
According to the fourth aspect of the invention, the focus control unit performs the auto focus control based on the image signal read in the high-speed read mode, so that the speed of the auto focus control can be increased. The display means updates and displays an image based on the image signal read in the high-speed read mode in a partial area within the display area when the auto focus control is being performed, and displays another area different from the partial area. , Information about the shooting is displayed. Therefore, it is possible to avoid a situation in which the image is not updated at all during the auto focus control, and the operator can more surely confirm the subject, and also can confirm the information regarding the shooting. is there.
[0141]
According to the fifth aspect of the present invention, when the instruction input is input, the focus control means performs the auto focus control based on the image signal read in the second mode. Can be achieved. The display means updates and displays an image based on the image signal read in the first mode in the display area when the instruction input is not input, and reads out the image in the second mode when the instruction input is input. An image based on the image signal is updated and displayed in the display area. Therefore, it is possible to avoid a situation in which the image is not updated at all during the autofocus control, and the operator can more surely confirm the subject. The image based on the image signal read in the second mode is displayed instead of the image based on the image signal read in the first mode when an instruction input from the operator is input. is there. Therefore, the operator can predict a change in the display state, so that the operator's discomfort can be reduced.
[Brief description of the drawings]
FIG. 1 is a front view showing an external configuration of a digital camera.
FIG. 2 is a top view illustrating an external configuration of the digital camera.
FIG. 3 is a rear view illustrating an external configuration of the digital camera.
FIG. 4 is a block diagram showing internal functions of the digital camera.
FIG. 5 is a diagram illustrating a concept of image reading in a draft mode.
FIG. 6 is a diagram illustrating a concept of image reading in an automatic focusing mode.
FIG. 7 is a block diagram showing main functions at the time of live view display.
FIG. 8 is a diagram showing a display screen at the time of autofocus control.
FIG. 9 is a timing chart showing an operation in the digital camera.
FIG. 10 is a conceptual diagram showing a read operation from a CCD image sensor.
FIG. 11 is a diagram showing a screen on which a cursor for specifying a focus position is displayed.
FIG. 12 is a diagram showing another display screen at the time of autofocus control.
FIG. 13 is a diagram showing another display screen at the time of autofocus control.
FIG. 14 is a diagram showing another display screen at the time of autofocus control.
FIG. 15 is a diagram showing a display screen according to the second embodiment.
FIG. 16 is a diagram showing another display screen.
FIG. 17 is a diagram showing a display screen of the LCD 5 before the shutter button 9 is pressed.
FIG. 18 is a diagram showing a display screen according to the third embodiment.
FIG. 19 is a flowchart according to a modification.
[Explanation of symbols]
1 Digital camera
2 Shooting lens
5 LCD
7 Control buttons
9 Shutter button
BB background image
BC, BL, BU Strip area
CR cursor
Dc cursor position information
Information on Dr Digital Camera Settings
Information on Dm AF control evaluation value
T1, T2, T3, T4, T5 period

Claims (5)

An electronic camera,
An image sensor that converts a subject image into an image signal by photoelectric conversion,
Display means having a display area for displaying an image based on the image signal,
Focusing control means for performing autofocus control based on the image signal,
With
The image sensor includes, as a read mode of the image signal, a first mode for reading an image signal corresponding to a predetermined number of pixels among all the pixels in the image sensor, and A second mode for reading out a plurality of images at high speed by reading out image signals corresponding to a small number of pixels,
The focusing control means performs autofocus control based on the image signal read in the second mode,
When the autofocus control is being performed, the display unit is configured to read out the first image based on the image signal that was read out in the first mode before shifting to the second mode, and read out the first image in the second mode. An electronic camera characterized by updating and displaying a composite image with a second image based on an image signal. The electronic camera according to claim 1,
The display area is divided into a first area and a second area,
The electronic camera, wherein the display unit displays the first image in the first area, and displays the second image in the second area. An electronic camera,
An image sensor that converts a subject image into an image signal by photoelectric conversion,
Display means having a display area for displaying an image based on the image signal,
Focusing control means for performing autofocus control based on the image signal,
With
The image sensor includes, as a read mode of the image signal, a first mode for reading an image signal corresponding to a predetermined number of pixels among all the pixels in the image sensor, and A second mode for reading out a plurality of images at high speed by reading out image signals corresponding to a small number of pixels,
The focusing control means performs autofocus control based on the image signal read in the second mode,
The electronic camera, wherein the display unit updates and displays an enlarged image based on the image signal read in the second mode when the autofocus control is being performed. An electronic camera,
An image sensor that converts a subject image into an image signal by photoelectric conversion,
Display means having a display area for displaying an image based on the image signal,
Focusing control means for performing autofocus control based on the image signal,
With
The image sensor has a high-speed read mode in which a plurality of images are read at a high speed by reading an image signal corresponding to a part of pixels among all pixels in the image sensor as a read mode of the image signal,
The focusing control means performs autofocus control based on the image signal read in the high-speed reading mode,
The display unit updates and displays an image based on the image signal read in the high-speed read mode in a partial area in the display area when the autofocus control is performed, and is different from the partial area. An electronic camera, wherein information related to shooting is displayed in another area. An electronic camera,
An image sensor that converts a subject image into an image signal by photoelectric conversion,
Display means having a display area for displaying an image based on the image signal,
Focusing control means for performing autofocus control based on the image signal,
Input means for receiving an instruction input from an operator indicating that autofocus control should be performed at high speed;
With
The image sensor includes, as a read mode of the image signal, a first mode for reading an image signal corresponding to a predetermined number of pixels among all the pixels in the image sensor, and A second mode for reading out a plurality of images at high speed by reading out image signals corresponding to a small number of pixels,
The focus control means performs autofocus control based on the image signal read in the first mode when the instruction input is not input, and reads in the second mode when the instruction input is input. Perform auto focus control based on the output image signal,
The display means updates and displays an image based on the image signal read in the first mode in the display area when the instruction input is not input, and in the second mode when the instruction input is input. An electronic camera, wherein an image based on a read image signal is updated and displayed in the display area.

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