JP2004312432A - Electronic camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic camera capable of photographing a picture without making photographer miss a photo opportunity, in response to all of photographing situation including impossible AF focusing. <P>SOLUTION: The electronic camera comprises an imaging means for converting information photographed using a photoelectric conversion device such as a solid imaging device into electrical signals, an image processing means for conducting various conversion processing for the electrical signals, a focusing means for conducting focusing or focal detection to an object, a photometry means for measuring luminance of the object and its periphery, and a setting means for setting up a f-stop using information from the photometry means. The electronic camera is characterized in that photographing is conducted by changing the f-stop set by a control means and changing a luminance bandpass of the imaging means, when focusing or focal detection can not be done by the focusing means. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to autofocus (AF) and control of an aperture of an electronic camera having a photographing optical system that converts photographed image information into an electric signal using a solid-state imaging device.
[0002]
[Prior art]
FIG. 9 is a cross-sectional view showing the configuration of a conventional single-lens reflex type electronic camera. A solid-state image sensor (CCD) is formed by using a focus detection device based on a known phase detection method in which a subject image passing through a photographing lens using FIG. The path up to forming an image in the focused state will be described above. 5, reference numeral 501 denotes a camera body; 502, a camera-side mount; and a photographing lens 503, which is detachably mounted on the camera-side mount. A subject light beam that has passed through the objective lens group 504 of the photographing lens 503 is changed from the state in which the main mirror 505, which is a half mirror, is shown in the figure to the object lens group 504 indicated by a two-dot chain line and a solid-state image sensor 506 (CCD). When it is in a state of being retracted from the subject light beam, the light passes through the optical filter 508 which is located behind the main mirror 505 and is arranged in front of the shutter 507 and cuts a specific wavelength of the photographing light beam or removes a high-frequency component thereof. When the shutter first curtain 507a travels and the shutter rear curtain 507b travels after a lapse of a predetermined time, the subject image is displayed on a solid-state image sensor 506 such as a CCD attached from the rear lid 509 at the same position as the focal image plane of the silver halide film. Is imaged. The subject luminous flux accumulated for a predetermined time is converted into an electric signal in an amount proportional to the light intensity, and the signal is transferred and recorded as a video signal in a camera or an external recording device. On the other hand, the path of the light beam for observing and confirming the subject is first reflected by the main mirror 505, which is a half mirror, in a substantially right angle direction to form a subject image on the focus plate 510. Further, after passing through the condenser lens 511, this light beam is turned into an upside-down upright image by the upright image forming element composed of the pentaprism 512, and the photographer observes the approximately erect image through the eyepiece lens 513. Further, the remaining part of the subject light flux is transmitted through the main mirror 505 and refracted by a sub-mirror 514 that totally reflects the light, and is guided to well-known autofocus optical systems 515, 516, and 517, and an autofocus sensor 518, thereby using a well-known method. Focus detection.
[0003]
[Problems to be solved by the invention]
In an electronic camera equipped with a focus detection device using the above-described phase difference method, when the contrast of the subject is extremely low or dark, or when the subject is in an extreme backlight state, focusing by the focus detection device is difficult. Since it is not possible, the photographer focuses on another object near the subject, fires a strobe, switches the focus detection operation from automatic (= AF) to manual (= MF), and focuses. The pre-shooting operation is required, and when this operation moves the subject, it often happens that an optimal photo opportunity is missed.
[0004]
Accordingly, the first object of the present application is to increase the AF focusing rate because a photograph that is in focus and free from camera shake can be taken without missing a shutter chance when AF focusing is not possible. The second purpose is to reduce the aperture as a specific means for focusing in the first purpose, to increase the depth of the subject, and to focus on a certain distance before and after the center of the subject. It is to do. A third object is that the photographer can set whether or not to perform the focusing means in the first object when AF focusing is impossible. The fourth purpose is that when the AF focusing is impossible, the photographer can select beforehand whether or not to perform the focusing means in the first purpose before photographing. The fifth object is to provide a means for setting the means for focusing when the AF focusing is impossible even if the user has not previously selected the means for focusing in the first purpose before photographing. Is the thing. A sixth object is to have a display means for notifying the photographer that the focusing means in the first object is to be performed.
[0005]
[Means for Solving the Problems]
As a means for solving the above-mentioned problems, a configuration related to the present application includes an image pickup unit that converts information captured using a photoelectric conversion element such as a solid-state image pickup device into an electric signal, and an image processing unit that performs various conversion processes on the electric signal. An electronic camera comprising: a distance measuring unit that measures a distance to a subject or a focus; a photometric unit that measures luminance of a subject and its surroundings; and a control unit that sets an aperture value based on information from the photometric unit. In the above, when the distance measurement or the focus detection by the distance measuring means is impossible, the aperture value set by the control means is changed and the luminance band (gain width) of the imaging means is changed to perform photographing. It is characterized by. With the above configuration, even in a shooting state where distance measurement or focusing is not possible, the aperture is narrowed down to increase the depth of the subject, and the subject is focused at a certain distance before and after the subject By doing so, shooting becomes possible. However, when the aperture is stopped down, the shutter time is delayed, which causes camera shake. Therefore, the luminance band (gain width) of the CCD is increased. As a result, the shutter time does not need to be changed. Therefore, even when the conventional AF focusing is impossible when a wide-angle lens is used, an image that is focused and has no camera shake can be taken without missing a photo opportunity, so that the AF focusing rate is increased.
[0006]
The second invention according to the present application is characterized in that, in addition to the structure of the first invention, the aperture value is changed in a direction to increase. With the above-described configuration, the direction of changing the aperture, which has not been clarified in the first invention, is determined as the aperture-down direction, so that the subject can be focused on at a certain distance before and after the subject, and shooting can be performed.
[0007]
Further, according to a third aspect of the present invention, in the electronic camera of the first and second aspects, the aperture value set by the control means is changed when the distance measurement or focus detection by the distance measurement means is impossible. And a setting means for setting whether or not to perform imaging by changing the luminance band (gain width) of the imaging means. With the above configuration, the photographer can select whether or not to change the aperture value.
[0008]
According to a fourth aspect of the present invention, in the electronic camera of the first and second aspects, when the distance measurement or the focus detection cannot be performed by the distance measurement means, the aperture value set by the control means is changed. It is characterized by having a selection means capable of selecting beforehand whether or not to change the luminance band (gain width) of the imaging means and to perform shooting before shooting. With the above configuration, whether or not to change the aperture value before photographing is selected, so if the distance measurement or focus detection by the distance measuring means is impossible, the photographer does not panic and the camera is instantaneous. Since the aperture value is changed at the same time, it is possible to select whether or not to change the aperture value in the same manner as in the third invention, and at the same time, it is possible to take an image that is in focus and without camera shake without missing a photo opportunity. Improve the focus rate.
[0009]
Next, a fifth invention according to the present application is the electronic camera according to the fourth invention, wherein the aperture value set by the control means is changed by the selection means which can be selected before photographing, and the luminance band of the imaging means is changed. If the distance measurement or focus detection by the distance measuring means is not possible without selecting to perform photographing by changing the gain width, the aperture value set by the control means is changed and the imaging means is controlled. It is characterized in that it has a setting means capable of setting the shooting by changing the luminance band (gain width). In the fourth invention, when the change of the aperture value is not selected by the selecting means, the change cannot be made immediately before the photographing. However, in the present invention, the setting can be made by the setting means.
[0010]
Further, according to a sixth aspect of the present invention, in the electronic camera according to the third, fourth, or fifth aspect, when the distance measurement or the focus detection by the distance measurement means is impossible, the aperture value set by the control means is set. And a display means for notifying the photographer before photographing that the luminance band (gain width) of the image pickup means is to be changed. With this configuration, the photographer can confirm on the display member such as the viewfinder that the camera executes the aperture value change in the case of AFNG.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
1 and 2 are a front perspective view and a rear perspective view showing the appearance of an embodiment of an electronic camera. In FIG. 1, reference numeral 1 denotes a camera body to which a photographing lens 2 shown can be interchangeably mounted. The grip 3 is shaped so that the photographer can easily hold the camera body 1. Various operation members and display members for photographing are concentrated on the upper portion of the camera body 1. The shutter release button of No. 4 performs photometry and distance measurement by pressing the first step (SW1), and starts a series of operations for exposure by pressing the second step (SW2). Reference numeral 5 denotes an upper display panel using liquid crystal, which displays information necessary for photographing, such as a shutter speed and an aperture value. Reference numeral 6 denotes an electronic dial disposed above the grip 3 and behind the shutter release button 4. The photographer can operate this dial to change shooting conditions such as shutter speed and aperture. Reference numeral 7 denotes a mode change button which can be changed to each of a shooting mode (program, shutter speed priority, aperture priority, manual, etc.) and a reproduction mode for reproducing a captured image. Reference numeral 8 denotes a main switch as a main power supply. Reference numeral 9 denotes a rear display panel which displays the remaining power state and the number of recordable images. Reference numeral 10 denotes a delete button for erasing photographed data. 11, a SCSI cable port; and 12, an AC adapter input port. Reference numeral 13 denotes a finder eyepiece window. Reference numeral 14 denotes a liquid crystal monitor (14a) and its operation buttons (14b). Reference numeral 15 denotes a stop-down button for pressing this button when the focusing by the focus detection device cannot be performed and for entering a stop-down mode for stopping down.
[0012]
FIG. 3 is a view showing a viewfinder display viewed from the viewfinder eyepiece window 13. In FIG. 3, reference numeral 20 denotes a visual field frame for restricting a viewable range of a photographer, and reference numeral 21 denotes a case where an object is placed within this range. This is a focus area where an accurate focus detection operation is not performed unless the shutter release button 4 is pressed. An exposure information display unit 22 displays exposure information such as an aperture value, a shutter speed, and completion of flash charging to a photographer. In FIG. 3A in which the exposure information display section 22 is enlarged and displayed, 22a is a focus mark which is turned on when AF focusing has been performed, and blinks when AF focusing has not been performed to notify the photographer of the focus state. . Reference numeral 22b denotes a stop-down mark for notifying a photographer that the camera is in a stop-down mode for stopping down when AF focusing cannot be performed.
[0013]
FIGS. 4A and 4B are flowcharts showing a photographing sequence in the first embodiment, and FIG. 5 is a view showing a display of the exposure information display section 22 in the finder at that time. FIG. 6 is a block diagram showing the configuration of the electronic camera according to the present embodiment. A series of operations in actual photographing will be described with reference to FIGS.
[0014]
In FIG. 4, when the main switch 8 is turned on in step 51, the camera checks the power state of the battery in step 52, resets the CPU in the main microcomputer 30 to an initial state, and then enters a standby state in which photographing is possible. In step 53, the photographing mode is set by pressing the mode change button 7 or a photographing mode setting operation such as outputting a signal from the main microcomputer 30 for automatically setting a CCD gain value corresponding to the ISO sensitivity of the conventional silver halide film. In step 54, when the shutter release button 4 is pressed down to the first step (SW1), in step 55, the photometry calculation and the distance measurement calculation are performed by the known photometry means and distance measurement means, and based on the calculation results, the main microcomputer 30 The focus lens group 32 is moved to the automatic focus driving unit 31 so that the focus of the photographing lens is adjusted to the optimum position. In step 56, the main microcomputer 30 determines whether or not the distance measurement (focusing) has been performed in step 55. If the distance measurement (focusing) cannot be performed, the process proceeds to step 58, where the main microcomputer 30 determines whether the distance measurement (focusing) has been completed. Both the focus mark 22a and the aperture mark 22b in the viewfinder LCD 34 shown in FIG. 5a are blinked via the driver 33, and a display is displayed to prompt the photographer that focusing was not possible and whether to select an aperture mode. I do. On the other hand, if the distance measurement (focusing) has been completed, the process proceeds to step 57, where only the focus mark 22a is lit and displayed as shown in FIG. In step 59, the photographer selects whether to enter the narrow-down mode by pressing or not pressing the narrow-down button 15 in FIG. 2. If the narrow-down mode is selected, the process proceeds to step 61. If not selected, the process proceeds to step 60 with the state of FIG. 5a. In step 61 in which the narrowing-down mode is selected, the focusing mark 22a is turned off and the narrowing-down mark 22b is turned on as shown in FIG. 5C. In step 62, the amount of reduction in light amount caused by changing the aperture value at the same time as calculating the aperture value is corrected by increasing the CCD gain value set by the main microcomputer 30 in step 53 in a predetermined step, and proceeds to the next step. . In step 63, the focus lens group 32 is moved so as to focus on the shortest photographing distance, that is, the hyperfocal distance when panning is completed, and at the same time, the changed aperture value is displayed in the viewfinder, and the focus mark 22a is lit ( Figure 5d). When the shutter release button 4 is further pressed in step 64 (SW2), the diaphragm value is obtained in step 55 when the distance measurement (focusing) is achieved in step 65, and the aperture value in step 62 is obtained when the distance measurement (focusing) cannot be performed. The aperture 36 is adjusted by the aperture drive member 35 so that In step 66, the main mirror is raised. When a predetermined time has elapsed after the start of the front curtain of the shutter at step 67, the rear curtain is driven, and at step 68, the main mirror is lowered. In step 69, the subject light accumulated on the solid-state imaging device 37 for a predetermined time is converted into an electric signal in an amount proportional to the light intensity. In step 70, the signal is subjected to analog processing in the pre-processing section 38. In the next step 71, the analog electric signal is converted into digital data by the AD converter 39. In step 72, the digitized signal undergoes some conversion processing in the signal processing unit 40, and is output to the memory controller 41. In order to display the photographed image on the liquid crystal display monitor 14a, it is necessary to use the photographing mode change button 7 to change from the photographing mode to the playback mode (= YES in step 73). When the button 14b is pressed, the process proceeds to step 74, where the memory controller 41 stores the image signal input from the signal processing unit 40 in the frame memory 42, and then transfers it to the main microcomputer 30 to perform image compression processing. Thereafter, the compressed image signal is displayed as a shooting screen on the liquid crystal display monitor 14a from the LCD driver 33 via the main microcomputer 30 in step 75. On the other hand, if not displayed (= no in step 73), the process proceeds to step 76, where the image signal stored in the frame memory 42 is also given to the storage memory 43 and stored. In step 77, the image signal in the storage memory 43 is written by the PC card controller 44 to a card type storage medium such as a PC card 45.
[0015]
By adopting such a configuration, the photographer can confirm that the mode has been switched to the narrowing-down mode even when AF focusing is impossible, and then an image that is in focus and is free from camera shake can be taken, thereby increasing the focusing rate. I do.
[0016]
FIGS. 7A and 7B are flowcharts showing a photographing sequence in the second embodiment, and FIG. 8 is a diagram showing a display of the exposure information display section 22 in the finder at that time. A series of operations in actual photographing will be described with reference to FIGS.
[0017]
In FIG. 7, when the main switch 8 is turned on in step 151, the camera checks the power state of the battery in step 152, resets the CPU in the main microcomputer 30 to an initial state, and then enters a standby state in which photographing is possible. In step 153, a photographing mode setting operation is performed by pressing the mode change button 7 to set a photographing mode or outputting a signal from the main microcomputer 30 for automatically setting a CCD gain value corresponding to the ISO sensitivity of the conventional silver halide film. At step 154, a selection is made as to whether or not to enter the narrowing-down mode. When the narrowing-down button 15 is pressed to select this mode, the process proceeds to step 155. When the mode is not pressed, that is, when the mode is not selected, step 165 of FIG. Proceed to. In the next step 155, as shown in FIG. 8A, the stop-down mark 22b in the viewfinder LCD 34 is illuminated and displayed in the viewfinder, and if the distance measurement (focusing) cannot be performed, the stop-down mode for automatically stopping down has been selected. To the photographer. In step 156, when the shutter release button 4 is pressed down to the first step (SW1), in step 157, a photometric operation and a distance measuring (focusing) operation are performed by a known photometric and distance measuring (focusing) means, and the calculation result is used as a basis. Then, the main microcomputer 30 moves the focus lens group 32 to the automatic focus driving unit 31 so as to adjust the focus of the photographing lens to the optimum position. In step 158, it is determined whether or not the distance measurement (focusing) has been performed in step 157. If the distance measurement (focusing) has not been performed, the process proceeds to step 159, and the focusing in the finder LCD 34 as shown in FIG. The mark 22a flashes to notify the photographer that focusing could not be performed. On the other hand, if the distance measurement (focusing) has been completed, the process proceeds to step 160, where the focus mark 22a is lit and displayed as shown in FIG. While the focus mark is blinking in step 159, in step 161 the aperture value is calculated, and at the same time, the amount of decrease in the amount of light caused by changing the aperture value is calculated by the CCD gain value set by the main microcomputer 30 in step 153. The correction is performed by raising the position by a predetermined number, and the process proceeds to the next step. In step 162, the focus lens group 32 is moved so as to focus on the shortest photographing distance, ie, the hyperfocal distance, which is a pan focus when the aperture is stopped down, and the changed aperture value is displayed, and the focus mark 22a in the viewfinder LCD 34 is turned on. (FIG. 8d). The photographing sequence after step 163 is the same as the photographing sequence of the first embodiment after step 64 in the flowchart of FIG. On the other hand, if the aperture mode has not been selected, the process proceeds to step 164 as shown in FIG. 7, where the shutter release button 4 is pressed (SW1), and in step 165, the photometry is performed by the known photometry and distance measurement (focusing) means. The main microcomputer 30 moves the focus lens group 32 to the automatic focus drive unit 31 based on the calculation result and the distance measurement (focusing) calculation, and adjusts the focus of the photographing lens to the optimum position. In step 165, it is determined whether or not the distance measurement (focusing) has been performed. If the distance measurement (focusing) has not been performed, the process proceeds to step 167, where the focus mark 22a in the viewfinder LCD 34 blinks, and the focus cannot be determined. Let the photographer know that. On the other hand, if the distance measurement (focusing) has been completed, the process proceeds to step 168, where the focus mark 22a is lit and displayed as shown in FIG. 5B to notify the photographer of the focus. Thereafter, the process proceeds to step 163. By adopting such a configuration, even when AF focusing is not possible, an image that is quickly focused and free from camera shake can be taken without missing a photo opportunity, so that the focusing rate is increased.
[0018]
【The invention's effect】
As described above, according to the present invention, an imaging unit that converts information captured using a photoelectric conversion element such as a solid-state imaging device into an electric signal, an image processing unit that performs various conversion processes on the electric signal, and An electronic camera comprising a distance measuring means for performing distance measurement or focus detection, a light measuring means for measuring luminance of a subject and its surroundings, and a control means for setting an aperture value based on information from the light measuring means. When the distance or the focus cannot be detected, shooting is performed by changing the aperture value set by the control unit and changing the luminance band (gain width) of the imaging unit. With this configuration, even if the photographer cannot focus, the aperture is narrowed down and the gain of the CCD is increased, so that even if AF focusing is not possible, an image that is focused and has no camera shake can be taken. Comes up. Therefore, the photographer can perform photographing without missing a photo opportunity in accordance with all photographing situations including AF inability to focus.
[0019]
Further, in the above configuration, the photographer can select whether or not to perform the change operation by having one or both of setting means capable of setting whether to perform the change operation or selection means that can be selected in advance before photographing. At the same time, an image that is in focus and has no camera shake can be taken without missing a photo opportunity, thereby increasing the AF focusing rate.
[0020]
Further, in the above configuration, the display means for notifying the photographer before the photographing that the change operation is to be performed enables the photographer to perform the photographing after confirming the change operation.
[Brief description of the drawings]
FIG. 1 is a front perspective view showing the appearance of an electronic camera according to the embodiment. FIG. 2 is a rear perspective view showing the appearance of the electronic camera according to the embodiment. FIG. 3 is a view showing a finder display. FIG. 5 is a view showing an exposure information display unit in a viewfinder according to the first embodiment. FIG. 6 is a block diagram showing a configuration of an electronic camera according to the present embodiment. FIG. 8 is a view showing an exposure information display section in a finder according to a second embodiment. FIG. 9 is a cross-sectional view showing a configuration of a single-lens reflex type electronic camera in a conventional example. [Explanation of symbols]
1 Mode change button 21 Focus area 22 Information display section 22a Focus mark 22b Refinement mark

Claims (6)

Imaging means for converting information photographed using a photoelectric conversion element such as a solid-state imaging element into an electric signal; image processing means for performing various conversion processes on the electric signal; and measurement for performing distance measurement or focus detection to a subject. In an electronic camera including a distance unit, a photometric unit that measures luminance of a subject and its surroundings, and a control unit that sets an aperture value based on information from the photometric unit,
When the distance measurement or the focus detection by the distance measuring means is impossible, the aperture value set by the control means is changed and the luminance band (gain width) of the imaging means is changed to perform photographing. Electronic camera. 2. The electronic camera according to claim 1, wherein the aperture value is changed to a larger value. In the electronic camera according to claim 1, when the distance measurement or focus detection by the distance measuring means is impossible, the aperture value set by the control means is changed and the luminance band (gain width) of the imaging means is changed. It is characterized by having a setting means capable of setting whether to change the shooting. In the electronic camera according to claim 1, when the distance measurement or focus detection by the distance measurement means is impossible, the aperture value set by the control means is changed and the luminance band (gain width) of the image pickup means. It is characterized in that it has a selecting means for selecting beforehand whether or not to perform photographing by changing. The electronic camera according to claim 4, wherein the photographing is performed by changing the aperture value set by the control means and changing the luminance band (gain width) of the imaging means by the selection means which can be selected in advance before photographing. If distance measurement or focus detection by the distance measuring means is not possible without selection, the aperture value set by the control means is changed, and the luminance band (gain width) of the imaging means is changed to perform photographing. It is characterized by having setting means for setting what to do. In the electronic camera according to claim 3, when the distance measurement or focus detection by the distance measurement means is impossible, the aperture value set by the control means is changed and the luminance band (gain) of the image pickup means is changed. It is characterized by having a display means for notifying the photographer of changing the width before photographing.

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