JP2008244587A - Camera and electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the visibility of a camera and an electronic apparatus display device. <P>SOLUTION: A photometric sensor 153 capable of measuring the luminance distribution of the back surface of a camera 1 is used to detect the luminance (facial luminance Ba) of the face portion of a photographer and the luminance (peripheral luminance Bb) of the periphery of the face portion. It is determined whether the camera is in a backlight condition, by determining the high and low relation between the face luminance Ba and the peripheral luminance Bb. If the face luminance Ba is higher than the peripheral luminance Bb, it is determined that the camera is in the backlight state, and the luminance of a backlight 7b is increased. In this way, if the face of a subject is irradiated directly with a light from a light source in the backlight state and the user's face is reflected on the display surface of the display monitor 7 or the surface of a protective glass, deterioration in the visibility of the display monitor 7 is suppressed and the visibility of the display monitor 7 can be ensured. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a camera and an electronic apparatus having a display device.

  There is known a camera that displays a subject image captured by an image sensor and various types of information related to photographing on a display monitor provided on the back surface. In this camera, the display brightness of the display monitor is controlled in accordance with the ambient light conditions such as the following light condition and the backlight condition (see Patent Document 1).

Japanese Patent Laid-Open No. 2004-15597

  However, with a conventional camera, the photographer's face irradiated with sunlight or the like is reflected on the protective glass surface of the display monitor or the like during backlighting, so the visibility of the display monitor may deteriorate.

(1) A camera according to a first aspect of the present invention is an image pickup means for picking up an image of a subject, a display device provided in a camera casing, and a luminance for measuring a luminance distribution in a direction in which the display surface of the display device is directed. A distribution measuring unit; a determining unit that determines a height relationship between the luminance of the first region in the luminance distribution measured by the luminance distribution measuring unit and the luminance of the second region around the first region; A luminance setting unit that sets a luminance value of the display device based on the result, and a display control unit that controls the display device so that the screen is displayed with the luminance value set by the luminance setting unit.
(2) According to the invention of claim 2, in the camera according to claim 1, the brightness setting means determines that the brightness is higher when the determination means determines that the brightness of the first area is lower than the brightness of the second area. When the value is set to the first value and the determination unit determines that the luminance of the first region is higher than the luminance of the second region, the luminance value is set to a second value larger than the first value. It is characterized by setting.
(3) The invention of claim 3 is the camera according to claim 2, wherein the brightness setting means determines that the brightness of the first area is lower than the brightness of the second area. However, when the brightness of the second region is higher than a predetermined value, the brightness value is set to a third value higher than the first value.
(4) The invention of claim 4 is the camera according to claim 1, further comprising ambient brightness detection means for detecting brightness around the camera, wherein the brightness setting means is detected by the ambient brightness detection means. When the brightness around the camera is lower than a predetermined threshold value, the luminance value is set to the first value or the fourth value lower than the first value regardless of the determination by the determination means. The brightness setting means sets the brightness value of the display device based on the determination result of the determination means when the ambient brightness of the camera detected by the ambient brightness detection means is higher than a predetermined threshold value. It is characterized by doing.
(5) The invention of claim 5 is the camera according to claim 4, further comprising a threshold value changing means for changing a predetermined threshold value based on a user's operation input.
(6) The camera according to claim 6 is characterized in that, in the camera according to claim 4, the ambient brightness detecting means is an imaging means, and detects the ambient brightness of the camera based on the output of the imaging means. And
(7) According to a seventh aspect of the present invention, in the camera according to the fourth aspect, the ambient brightness detecting means is a luminance distribution measuring means, and the luminance of the first area and the second area measured by the luminance distribution measuring means are measured. Brightness around the camera is detected based on at least one of luminance.
(8) The camera according to claim 8 is characterized in that, in the camera according to claim 1, the first region is a portion near the center of the measurement area measured by the luminance distribution measuring means.
(9) According to the ninth aspect of the present invention, there is provided a camera having an imaging means for capturing a subject image on a front surface of a camera housing, a display device provided on a rear surface of the housing, and a rear brightness for detecting the brightness of the rear surface. Luminance value determination means for determining the luminance value of the display device based on the detection means, the output of the imaging means, and the brightness of the back surface detected by the back surface brightness detection means, and the luminance value determined by the brightness value determination means And a brightness setting means for setting the brightness value of the display device, and a display control means for controlling the display device so that the screen is displayed with the brightness value set by the brightness setting means.
(10) In the camera according to claim 9, in the camera according to claim 9, the luminance value determining means is in a backlight state based on the output of the imaging means and the brightness of the back surface detected by the back surface brightness detecting means. If it is determined whether or not there is a follow light state, the luminance value is determined to be a first value, and if it is determined that the backlight is in a backlight state, the luminance value is higher than the first value. The second value is determined.
(11) The camera according to claim 11 is the camera according to claim 10, wherein the luminance value determining means is based on the output of the imaging means and the brightness of the back surface detected by the back surface brightness detecting means. Even if it is determined that the brightness of the back surface detected by the back surface brightness detection means is brighter than a predetermined brightness, the brightness value is set to a third value higher than the first value. It is characterized by determining to.
(12) The invention of claim 12 is the camera according to claim 9, further comprising ambient brightness detection means for detecting brightness around the camera, wherein the brightness setting means is detected by the ambient brightness detection means. When the brightness around the camera is lower than the predetermined threshold value, the brightness value of the display device is set to the first value or the first value lower than the first value regardless of the determination of the brightness value determining means. The brightness setting means is set to a value of 4, and when the ambient brightness of the camera detected by the ambient brightness detection means is higher than a predetermined threshold, based on the determination result of the brightness value determination means, A luminance value of the display device is set.
(13) The camera according to a thirteenth aspect is the camera according to the twelfth aspect, further comprising threshold value changing means for changing a predetermined threshold value based on a user operation input.
(14) The camera according to claim 14 is the camera according to claim 12, wherein the ambient brightness detection means is an imaging means, and detects ambient brightness of the camera based on an output of the imaging means. And
(15) The invention of claim 15 is the camera according to claim 12, wherein the ambient brightness detecting means is a back brightness detecting means, and the camera is based on the back brightness detected by the back brightness detecting means. It is characterized by detecting the brightness of the surrounding area.
(16) A camera according to a sixteenth aspect of the present invention is an image pickup means for picking up a subject image, a display device provided in the camera case, and a person in the subject image based on the subject image picked up by the image pickup means. Luminance for determining the luminance value of the display device based on the difference in brightness between the face recognition means for recognizing the face part, the area of the face part of the person recognized by the face recognition means, and the area around the face part A value determining means, a brightness setting means for setting the brightness value of the display device to the brightness value determined by the brightness value determining means, and the display device is controlled so that the screen is displayed with the brightness value set by the brightness setting means. And a display control means.
(17) In the camera according to claim 17, in the camera according to claim 16, the brightness value determining means includes brightness of a face area of the person recognized by the face recognition means and an area around the face area. Whether or not the backlight is in the backlight state. If the backlight is determined to be in the backlight state, the brightness value is determined to be the first value. If the backlight is determined to be in the backlight state, the brightness is determined. The value is determined to be a second value higher than the first value.
(18) In the camera according to claim 18, in the camera according to claim 17, the brightness value determining means is a brightness of the area of the face part of the person recognized by the face recognition means and the area around the face part. Even if it is determined that the light is in a follow-up state based on the difference between the two, if the brightness of the area around the face recognized by the face recognition means is brighter than the predetermined brightness, The luminance value is determined to be a third value higher than the first value.
(19) The invention of claim 19 is the camera according to claim 16, further comprising ambient brightness detection means for detecting brightness around the camera, wherein the brightness setting means is detected by the ambient brightness detection means. When the brightness around the camera is lower than the predetermined threshold value, the brightness value of the display device is set to the first value or the first value lower than the first value regardless of the determination of the brightness value determining means. The brightness setting means is set to a value of 4, and when the ambient brightness of the camera detected by the ambient brightness detection means is higher than a predetermined threshold, based on the determination result of the brightness value determination means, A luminance value of the display device is set.
(20) The invention of claim 20 is the camera according to claim 19, further comprising threshold value changing means for changing a predetermined threshold value based on a user's operation input.
(21) The camera according to claim 21 is the camera according to claim 19, wherein the ambient brightness detecting means is an imaging means, and detects the ambient brightness of the camera based on the output of the imaging means. And
(22) An electronic apparatus according to a twenty-second aspect of the present invention includes a display device provided in a housing, a luminance distribution measuring unit that measures a luminance distribution in a direction in which a display surface of the display device is directed, and a luminance distribution measuring unit. A determination unit that determines the level relationship between the luminance of the first region in the measured luminance distribution and the luminance of the second region around the first region, and the luminance value of the display device is set based on the determination result of the determination unit Brightness setting means, and display control means for controlling the display device so that the screen is displayed with the brightness value set by the brightness setting means.

  According to the present invention, the visibility of a display device can be improved.

--- First embodiment ---
A first embodiment of a camera according to the present invention will be described with reference to FIGS. FIG. 1A is a perspective view of the camera according to the first embodiment to which the present invention is applied as viewed from the front (front side), and FIG. 1B is a perspective view of the camera as viewed from the back (rear side). It is. For convenience of explanation, the vertical and horizontal directions and the front and rear direction of the camera are defined as shown in the figure.

  This camera 1 is a thin camera that is longer in the width direction (left-right direction) and thinner in thickness (front-rear direction length) than in the height direction (up-down direction). These are formed substantially parallel to each other, and the whole has a substantially rectangular parallelepiped shape. A camera body 10 which is a housing of the camera 1 is provided with a release button 2 on the right side of the upper surface, and a window portion 3 for a photographing lens and a light emitting portion 4 for irradiating a subject on the upper left portion of the front surface. ing.

  On the rear surface of the camera body 10, a zoom lever 5, a cross operation key 6, a display monitor 7, a DEL button 9a, a MENU button 9b, a MODE button 9c, a PLAY button 9d, and a photometric sensor 153 are provided. It has been. The imaging optical system of the camera 1 is configured as a refractive optical system that refracts a subject light beam incident from the window 3 in the height direction.

  The release button 2 is an operation button for performing a release operation. The zoom lever 5 is an operation lever for performing an operation of changing the focal length of an imaging optical system arranged in a lens barrel (not shown), and can be operated by pressing the left and right ends. The cross operation key 6 is an operation button for selecting various menu items and the like, and can be operated in the up / down / left / right direction and the down direction.

  The display monitor 7 is, for example, a non-self-luminous liquid crystal display (LCD), and includes a display module 7a for displaying display contents and a backlight 7b for illuminating the display module 7a. The display monitor 7 functions as a display monitor that displays an image obtained by imaging and various menu screens, and also functions as an electronic viewfinder that displays an image of a subject (through image) at the time of imaging.

  The DEL button 9a is an operation button (erase button) that is operated when erasing an image obtained by imaging. The MENU button 9b is an operation button that is operated when a menu screen for setting various functions is displayed on the display monitor 7. The MODE button 9c is an operation button that is operated when the imaging mode is selected. The PLAY button 9d is an operation button (playback button) operated when displaying a captured image on the display monitor 7.

  The photometric sensor 153 is a sensor that measures the direction in which the display surface of the display monitor 7 is directed, that is, the luminance distribution on the back surface of the camera 1. Measurement of the luminance distribution on the back surface of the camera 1 by the photometric sensor 153 will be described later.

  FIG. 2 is a block diagram illustrating the configuration of the camera 1. The arithmetic circuit 101 is configured by a microcomputer or the like. The arithmetic circuit 101 receives a signal output from each unit described later, performs a predetermined calculation, and outputs a control signal based on the calculation result to each unit. The arithmetic circuit 101 and each unit described later are connected to each other.

  The image sensor 202 is configured by a CCD image sensor or the like. The image sensor 202 captures an image of subject light that has passed through a lens barrel (not shown), and outputs an image signal to the image processing unit 123. The image processing unit 123 is configured by an A / D conversion circuit, an ASIC, and the like. The image processing unit 123 converts an analog imaging signal into a digital signal, performs image processing such as white balance processing on the image data after digital conversion, and compression processing that compresses the image data after image processing in a predetermined format Then, decompression processing for decompressing the compressed image data is performed.

  The release switch 141 outputs a release operation signal to the arithmetic circuit 101 in conjunction with the release button 2. The release operation signal includes a half-press operation signal corresponding to a half-press operation of the release button 2 and a full-press operation signal corresponding to a full-press operation pressed deeper than the half-press operation.

  The DEL switch 143, the MENU switch 144, the MODE switch 145, and the PLAY switch 146 output an operation signal to the arithmetic circuit 101 when the DEL button 9a, the MENU button 9b, the MODE button 9c, and the PLAY button 9d are pressed. .

  The cross key switch 147 outputs a signal corresponding to the operation of the cross operation key 6 to the arithmetic circuit 101. When the upper part of the cross operation key 6 is pressed, the cross key switch 147 outputs an upward signal. When the lower part of the cross key 6 is pressed, the cross key switch 147 outputs a downward signal. When the right portion of the cross operation key 6 is pressed, the cross key switch 147 outputs a right direction signal. When the left portion of the cross operation key 6 is pressed, the cross key switch 147 outputs a left direction signal. When the cross operation key 6 is depressed, the cross key switch 147 outputs a depression signal.

  The zoom switch 151 outputs a signal corresponding to the operation of the zoom lever 5 to the arithmetic circuit 101. When the right end of the zoom lever 5 is pressed, the zoom switch 151 outputs a telephoto instruction signal, and when the left end of the zoom lever 5 is pressed, the first zoom switch 151 outputs a wide-angle instruction signal. The photometric sensor 153 outputs a signal representing the measurement result of the luminance distribution to the arithmetic circuit 101.

  The display control unit 161 is a control unit that performs display control of the display module 7 a based on a signal output from the arithmetic circuit 101. The backlight driving unit 162 is a circuit that drives the backlight 7b of the display monitor 7, and controls the brightness (luminance) of the backlight 7b based on a signal output from the arithmetic circuit 101.

  The lens drive control unit 163 drives a lens group of a lens barrel (not shown) so as to perform a focusing operation and a focal length changing operation based on a signal output from the arithmetic circuit 101. Based on the signal output from the arithmetic circuit 101, the light emitting device 164 performs light emission control by instructing the light emitting unit 4 to start and stop light emission. The recording medium mounting unit 165 detachably holds a recording medium (not shown), reads and erases data recorded on the mounted recording medium, and writes data to the recording medium. Image data after image processing is recorded on the recording medium.

  With the camera 1 configured as described above, it is possible to capture a subject image and display the captured image on the display monitor 7. Although the camera 1 is carried and used in various places such as outdoors and indoors, the state of ambient light differs depending on the place and time zone, and the brightness of the surroundings of the camera 1 and the positional relationship with the light source of ambient light are different. Therefore, in order to improve the visibility of the display monitor 7, it is necessary to change the brightness of the backlight 7b according to the ambient brightness and the positional relationship with the light source of the ambient light. Therefore, in the camera 1 of the present embodiment, the brightness of the screen display of the display monitor 7 is increased by changing the brightness of the backlight 7b as follows.

--- Ambient light condition and visibility of display monitor 7 ---
FIG. 3 is a diagram illustrating a positional relationship among a light source (for example, the sun) of ambient light, the camera 1, a subject, and a photographer (user) in a normal light state. As shown in FIG. 3, in the normal light state, the light source is positioned on the back surface of the camera 1. Therefore, when the light from the ambient light source is strong, the visibility of the display monitor 7 decreases.

  FIG. 4 is a diagram illustrating a positional relationship among the light source of ambient light, the camera 1, the subject, and the photographer in the backlight state. As shown in FIG. 4, in the backlit state, the light source is located in front of the camera 1, so light from the light source is directly irradiated to the photographer, and the photographer's surface is displayed on the display monitor 7 or the surface of the protective glass. The face is reflected. Therefore, when the light from the ambient light source is strong, the visibility of the display monitor 7 decreases.

  As described above, the visibility of the display monitor 7 may be lowered depending on the positional relationship between the light source of the ambient light and the camera 1. However, in the imaging apparatus such as the camera 1, a subject exists, so the camera 1 (imaging apparatus) ) Is not easy to change direction.

  Therefore, in the camera 1 of the present embodiment, the ambient light state is detected using the photometric sensor 153, and the brightness (luminance) of the backlight 7b is determined in a situation where the visibility of the display monitor 7 is judged to be reduced. Raise. Specifically, as will be described below, the photometric sensor 153 measures the luminance of the area estimated as the photographer's face and the luminance of the surrounding area. And based on a measurement result, while determining whether it is a follow light state or a back light state, the brightness | luminance of the backlight 7b is raised in consideration of the intensity of the light from the light source of environmental light.

--- Structure of photometric sensor 153 ---
FIG. 5 is a diagram conceptually showing the configuration of the photometric sensor 153. The photometric sensor 153 includes a detection element 153a and a lens 153b. The detection element 153a is a photoelectric conversion element that outputs a current corresponding to the intensity of incident light when light is incident on the light receiving surface. For example, a silicon photo diode (SPD) is used. For example, as shown in FIG. 6A, the detection element 153a has a central photometric area 153c substantially at the center of the light receiving surface and a peripheral photometric area 153d outside the central photometric area.

  Note that the shape of the photometric area of the detection element 153a illustrated in FIG. 6A is an example. As shown in FIG. 6A, it is not essential to provide a central photometric area 153c located substantially at the center of the light receiving surface and a peripheral photometric area 153d surrounding the entire outer periphery of the central photometric area 153c. For example, as shown in FIG. 6 (b), a first photometry area located substantially at the center of the light receiving surface and having a lower surface in contact with the lower surface of the photometry area, for example, one of the first photometry areas adjacent to the first photometry area. You may provide the 2nd photometry area surrounding a part. As will be described later, if the luminance of the portion estimated to be the photographer's face and the luminance around the portion estimated to be the photographer's face can be detected respectively, the shape of the photometric area of the detection element 153a is particularly It is not limited.

  The lens 153b is a lens for condensing light from the back surface of the camera 1 on the light receiving surface of the detection element 153a. The light from the back surface of the camera 1 is condensed by the lens 153b as follows. 7A and 7B are diagrams showing the positional relationship among the camera 1, the subject, and the photographer. FIG. 7A is a top view and FIG. 7B is a side view. In a general photographing state, the distance l from the rear surface of the camera 1 to the photographer observing the display monitor 7 is about 15 to 40 cm.

  Assuming that the width Hx and length Hy of the photographer's face are about 14 cm and about 25 cm, respectively, the angle range θx in the left-right direction centering on the rearward axis from the center of the rear surface of the display monitor 7 is about 20 to 50 degrees. The photographer's face is positioned within the range of about 35 to 80 degrees as the angle range θy in the vertical direction. Therefore, in the camera 1 of the present embodiment, in consideration of the case of vertical position shooting, light from an angle range of about 20 degrees centering on an axis extending from the center of the rear surface of the display monitor 7 to the rear is obtained. The light is condensed on the central photometry area 153c of the detection element 153a by the lens 153b. Further, the light from outside the angle range of about 20 degrees centering on the axis extending backward from the center of the rear surface of the display monitor 7 is condensed on the peripheral photometry area 153d of the detection element 153a by the lens 153b. Therefore, the photometric sensor 153 detects the luminance of the region (part) estimated as the photographer's face in the central photometric area 153c, and the luminance of the peripheral region estimated as the photographer's face in the peripheral photometric area 153d. Can be detected. That is, the luminance distribution on the back surface of the camera 1 can be measured by the photometric sensor 153.

--- Judgment of direct light condition and backlight condition ---
As shown in FIG. 3, when the light is in the normal light state, the ambient light source is located behind the photographer. Therefore, when the photographer is viewed from the camera 1, the brightness of the photographer's face is lower than the surrounding brightness (the brightness of the photographer's background when the photographer is viewed from the camera 1). That is, as shown in FIG. 8A, the luminance (face luminance) Ba of the portion estimated to be the photographer's face detected in the central photometry area 153c is the face of the photographer detected in the peripheral photometry area 153d. It is lower than the luminance around the portion estimated as (brightness luminance) Bb. As described above, Ba <Bb in the follow-up state.

  Also, as shown in FIG. 4, in the backlight state, the ambient light source is positioned in front of the photographer. Therefore, when the photographer is viewed from the camera 1, the brightness of the photographer's face is higher than the surrounding brightness. That is, as shown in FIG. 8B, the facial brightness Ba detected in the central photometry area 153c is higher than the peripheral brightness Bb detected in the peripheral photometry area 153d. Thus, in the backlight state, Bb <Ba.

  Therefore, in the camera 1 of the present embodiment, the arithmetic circuit 101 compares the magnitude relationship between the face luminance Ba and the peripheral luminance Bb based on the detection signal from the photometric sensor 153. Then, the arithmetic operation circuit 101 determines that the light is in the backlight state if Ba <Bb, and determines that the light is in the backlight state if Bb <Ba.

--- About brightness control of backlight 7b ---
When a power switch (not shown) of the camera 1 is turned on and the camera 1 is activated, the backlight 7b is lit at a predetermined brightness B until the brightness control of the backlight 7b described below is performed. . That is, when the camera 1 is activated, the arithmetic circuit 101 controls the backlight driving unit 162 so that the backlight 7b is lit with the normal luminance B. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance B. Here, the brightness B is a brightness determined in advance from the viewpoint of visibility of the display monitor 7 and power saving.

(1) When the surroundings are bright (when the ambient light source is strong)
(1-1) Backlight State As described above, when the light from the ambient light source is strong and the backlight is in the backlight state, the visibility of the display monitor 7 is lowered by the ambient light source. Therefore, the arithmetic circuit 101 determines whether or not the intensity of the ambient light from the light source is so strong as to adversely affect the visibility of the display monitor 7. Specifically, if the detected ambient luminance Bb exceeds a predetermined luminance a2, the arithmetic circuit 101 is so strong that the intensity of light from the ambient light source adversely affects the visibility of the display monitor 7. Judge.

  If the arithmetic circuit 101 determines that the detected ambient luminance Bb exceeds the predetermined luminance a2 and is in the backlight state as described above, the arithmetic circuit 101 has a luminance (luminance C) higher than the normal luminance (luminance B). The backlight driving unit 162 is controlled so that the backlight 7b is turned on. That is, when the detected peripheral luminance Bb exceeds the predetermined luminance a2 and the arithmetic circuit 101 determines that the backlight 7b is in the backlight state as described above, the arithmetic circuit 101 changes the luminance level of the backlight 7b to the luminance C. The backlight driving unit 162 is controlled. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance C. As a result, the brightness of the display screen of the display monitor 7 increases, so that the visibility of the display monitor 7 is improved.

(1-2) Forward light state In the forward light state, even if the intensity of light from the ambient light source is strong enough to adversely affect the visibility of the display monitor 7 in the backlight state, in other words, Even if the detected peripheral luminance Bb exceeds the predetermined luminance a2, the visibility of the display monitor 7 is not deteriorated as much as in the backlight state. That is, in the normal light state, the visibility of the display monitor 7 deteriorates when the light from the ambient light source is strong. Accordingly, when the arithmetic circuit 101 determines that the detected peripheral luminance Bb is in the following light state as described above when the detected peripheral luminance Bb exceeds the predetermined luminance a2, the detected peripheral luminance Bb is higher than the luminance a2. It is determined whether or not a predetermined luminance a3 is exceeded.

  When the arithmetic circuit 101 determines that the detected peripheral luminance Bb exceeds the predetermined luminance a3 and is in the following light state as described above, the backlight driving unit 162 causes the backlight 7b to be lit at the luminance C. To control. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance C. As a result, the brightness of the display screen of the display monitor 7 increases, so that the visibility of the display monitor 7 is improved.

  Even if the arithmetic circuit 101 determines that the detected peripheral luminance Bb exceeds the predetermined luminance a2 and is in the following light state as described above, the detected peripheral luminance Bb is equal to or lower than the predetermined luminance a3. Is determined, the backlight drive unit 162 is controlled so that the backlight 7b is lit at the luminance B. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance B. As a result, the brightness of the display screen of the display monitor 7 is the same as the normal state. However, as described above, the visibility of the display monitor 7 is not deteriorated so much by the light from the ambient light source in the forward light state. The photographer can surely see the image displayed on the display monitor 7.

(2) When the surroundings are reasonably bright (when the light from the ambient light source is not so strong)
When the intensity of light from the ambient light source is not so strong as to adversely affect the visibility of the display monitor 7, that is, when the detected peripheral luminance Bb is equal to or lower than the predetermined luminance a2, the display monitor Therefore, it is not necessary to increase the luminance of the backlight 7b in order to improve the visibility. Therefore, when the arithmetic circuit 101 determines that the detected peripheral luminance Bb is equal to or lower than the predetermined luminance a2, the arithmetic circuit 101 controls the backlight driving unit 162 so that the backlight 7b is turned on at the luminance B. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance B. As a result, the brightness of the display screen of the display monitor 7 is the same as the normal state. However, as described above, the visibility of the display monitor 7 is not deteriorated by the light from the ambient light source. The image displayed on the monitor 7 can be visually recognized with certainty.

(3) When the surroundings are dark (when the light from the ambient light source is weak)
Note that when the light from the ambient light source is weak and the surroundings are dark, the photographer's eyes adapt to the darkness. Therefore, even if the brightness of the display screen of the display monitor 7 is lowered than the normal state, the visibility is low. Will not drop. Also, from the viewpoint of power saving, it is desirable to lower the brightness of the display screen of the display monitor 7 from the normal state. Conversely, if the brightness of the display screen of the display monitor 7 is the same as the normal state, the photographer The display monitor 7 may feel dazzling.

  Therefore, when the arithmetic circuit 101 determines that the detected peripheral luminance Bb is equal to or lower than the predetermined luminance a1 lower than the luminance a2 described above, the backlight 7b is turned on at a luminance lower than the luminance B (luminance A). The backlight driving unit 162 is controlled. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance A. As a result, the brightness of the display screen of the display monitor 7 is lower than that in the normal state. However, as described above, since the photographer's eyes adapt to darkness, the visibility of the display monitor 7 does not deteriorate.

  In addition, since the sun height (elevation angle) is different between morning and evening and daytime, extreme daylight / backlight does not occur in the daytime when the elevation angle of the sun is large, and the brightness of the display monitor 7 is increased so positively. There is no need to let them. On the contrary, in the morning or evening when the elevation angle of the sun is small, extreme forward / backlight occurs, so it is necessary to positively increase the luminance of the display monitor 7. Further, since the degree of light adaptation of the photographer is different between morning and evening and daytime, it is desirable to change the conditions for increasing the brightness of the display monitor 7 between morning and evening and daytime. Therefore, it is desirable to appropriately change the values of the luminances a1 to a3 described above in the morning, evening, and daytime.

  Since the color temperature of outdoor environmental light differs between morning and evening and daytime, the values of the above-described luminances a1 to a3 may be changed based on the color temperature of environmental light. Therefore, in the camera 1 of the present embodiment, the arithmetic circuit 101 estimates the color temperature of the ambient light based on the through image obtained by imaging with the imaging element 202. The arithmetic circuit 101 reads the values of the luminances a1 to a3 as appropriate from the map of the luminance values a1 to a3 stored in advance based on the estimated color temperature, and uses them for the luminance control of the backlight 7b described above. It is set as the value of luminance a1 to a3. Therefore, in the above-described luminance control of the backlight 7b, the determination is made based on the luminances a1 to a3 set according to the color temperature of the ambient light. It can be said that the luminances a1 to a3 described above are the threshold values of the brightness around the camera 1 regarding the visibility of the display monitor 7.

--- Timing of luminance change of backlight 7b ---
It is desirable not to increase the brightness of the backlight 7b even when the camera 1 is turned on, in order to save power, except when checking the composition at the time of shooting. However, it is desirable to improve the visibility of the display monitor 7 by immediately changing the luminance of the backlight 7b when checking the composition at the time of shooting. Therefore, in the camera 1 of the present embodiment, when the release button 2 is half-pressed, the luminance of the display monitor 7 is changed as described above.

--- Flow chart ---
FIG. 9 is a flowchart showing the processing contents of a program for performing the luminance change processing of the backlight 7b described above. After the power switch (not shown) is turned on, every time the release button 2 is pressed halfway and a half-press operation signal is received from the release switch 141, a program for performing this processing is started and the arithmetic circuit 101 Executed.

  In step S <b> 1, the luminance distribution measurement result is received from the photometric sensor 153. That is, in step S1, the values of the face luminance Ba and the peripheral luminance Bb are read from the photometric sensor 153. If step S1 is performed, it will progress to step S3, and based on the imaging signal of the through image from the image pick-up element 202, the color temperature of environmental light will be estimated and it will progress to step S5. In step S5, based on the color temperature of the ambient light estimated in step S3, the values of the luminances a1 to a3 are read from the previously stored map of the luminance a1 to a3 values, and the luminances a1 to a3 used for the following determinations. And proceed to step S7.

  In step S7, it is determined whether or not the peripheral luminance Bb read in step S1 is lower than the luminance a1 set in step S5. If a negative determination is made in step S7, the process proceeds to step S9, and it is determined whether or not the peripheral luminance Bb read in step S1 is lower than the luminance a2 set in step S5. If a negative determination is made in step S9, the process proceeds to step S11, and it is determined whether or not the peripheral luminance Bb read in step S1 is lower than the facial luminance Ba read in step S1.

  If the determination in step S11 is affirmative, that is, if it is determined that the light is backlit, the process proceeds to step S13, and the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance C, and the process ends. . If the determination in step S11 is negative, that is, if it is determined that the light is direct light, the process proceeds to step S15, and it is determined whether or not the peripheral luminance Bb read in step S1 is higher than the luminance a3 set in step S5. If an affirmative determination is made in step S15, the process proceeds to step S17, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance C, and the process is terminated.

  If a negative determination is made in step S15, the process proceeds to step S19, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance B, and the process is terminated.

  If an affirmative determination is made in step S9, the process proceeds to step S21, and the backlight drive unit 162 is controlled to change the luminance level of the backlight 7b to the luminance B, and the process is terminated.

  When an affirmative determination is made in step S7, the process proceeds to step S23, and the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance A, and the process is terminated.

The camera 1 according to the first embodiment described above has the following operational effects.
(1) Using the photometric sensor 153, the face luminance Ba and the peripheral luminance Bb are detected, and by determining the height relationship between the facial luminance Ba and the peripheral luminance Bb, it is determined whether or not the backlight is in the backlight state. The brightness level of the backlight 7b is set. Thereby, since it can be easily determined whether it is a backlight state or a follow light state, it can be easily determined whether the visibility of the display monitor 7 is adversely affected by the light source of the ambient light. Therefore, even when the visibility of the display monitor 7 is adversely affected by the light source of the ambient light, the brightness of the display screen of the display monitor 7 can be easily increased, so that the visibility of the display device can be improved. This is particularly effective for the camera 1 in which the orientation cannot be easily changed due to the presence of a subject.

(2) If the face brightness Ba is higher than the peripheral brightness Bb, it is determined that the backlight 7b is in a backlight state, and the brightness of the backlight 7b is increased. Thereby, even if light is directly irradiated to the photographer from the light source located in front of the photographer and the user's face is reflected on the display surface of the display monitor 7 or the surface of the protective glass, the visibility of the display monitor 7 is ensured. it can.

(3) Even if the face luminance Ba is lower than the peripheral luminance Bb, the luminance of the backlight 7b is increased if the peripheral luminance Bb is higher than the luminance a3. Thereby, even if light enters from the light source located behind the photographer and is reflected by the display surface of the display monitor 7 or the surface of the protective glass, the visibility of the display monitor 7 can be secured. The luminance a3 is a threshold value for determining whether to increase the luminance of the backlight 7b in the normal light state. The luminance a3 is set to a value higher than the luminance a2. As a result, the luminance of the backlight 7b increases only when the visibility of the display monitor 7 is reduced by the light from the ambient light source even in the normal light state, so that an unnecessary increase in power consumption can be prevented. .

(4) When the detected peripheral luminance Bb is equal to or lower than the luminance a2, the luminance of the backlight 7b is not increased, and when the detected peripheral luminance Bb is equal to or lower than the luminance a1, the backlight 7b The brightness was reduced. Thereby, the visibility of the display monitor 7 can be ensured and the power consumption can be reduced.

(5) The brightness a1 to a3 values are changed based on the color temperature of the ambient light. Thereby, since the brightness of the backlight 7b can be controlled in consideration of the difference in the elevation angle of the sun, the brightness of the backlight 7b suitable for the environment in which the camera 1 is placed can be controlled, and the visibility of the display monitor 7 can be secured. .

(6) The photometric sensor 153 is used to detect the face luminance Ba and the peripheral luminance Bb. Thereby, the brightness of the area near the photographer's face and the brightness of the surrounding area can be easily detected, so that it is easy to determine whether or not the camera is in the forward / backlight state. Therefore, since the brightness of the backlight 7b can be accurately controlled according to the state of the ambient light, the visibility of the display monitor 7 can be ensured under various environments.

(7) In the photometric sensor 153, the luminance of the portion estimated to be the photographer's face is detected in the central photometric area 153c, and the luminance around the portion estimated to be the photographer's face is detected in the peripheral photometric area 153d. Configured. As a result, the face luminance Ba and the peripheral luminance Bb can be simultaneously detected by one photometric sensor 153, and the number of photometric sensors 153 can be reduced to reduce the cost.

(8) When the release button 2 is half-pressed, the brightness of the display monitor 7 is immediately changed according to the state of the ambient light. Thereby, when the display monitor 7 needs to be confirmed, the brightness of the display monitor 7 is immediately changed, so that the visibility of the display monitor 7 can be improved and the power consumption can be suppressed.

--- Second Embodiment ---
A second embodiment of the camera according to the present invention will be described with reference to FIGS. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. In the present embodiment, instead of the photometric sensor 153, a photometric sensor 253 that measures the luminance of the entire back surface of the camera 1 is provided, and is based on the through image from the image sensor 202 and the measurement result of the photometric sensor 253. Thus, it differs from the first embodiment in that it is determined whether or not it is in a backlight state.

  FIG. 10 is a block diagram illustrating the configuration of the camera 1 according to the second embodiment. As described above, the camera 1 is provided with the photometric sensor 253 that measures the luminance of the entire back surface of the camera 1 instead of the photometric sensor 153 that can measure the luminance distribution of the back surface of the camera 1. The photometric sensor 253 does not have a structure capable of measuring the luminance distribution on the back surface of the camera 1, but merely measures the luminance of the entire back surface of the camera 1. Therefore, the photometric sensor 253 is less expensive than the photometric sensor 153. The photometric sensor 253 is disposed on the rear surface of the camera body 10 as in the camera 1 of the first embodiment.

--- Judgment of direct light condition and backlight condition ---
As shown in FIG. 3, when the light is in the normal light state, the ambient light source is located behind the photographer. For this reason, the luminance of the entire back surface of the camera 1 (back surface luminance Br) measured by the photometric sensor 253 is high, and the luminance of the entire through image obtained by imaging with the image sensor 202 (through image luminance Bf) is low. Also, as shown in FIG. 4, in the backlight state, the ambient light source is positioned in front of the photographer. Therefore, the back surface brightness Br measured by the photometric sensor 253 is low, and the through image brightness Bf is high.

  Therefore, in the camera 1 of the present embodiment, the arithmetic circuit 101 compares the magnitude relationship between the back surface brightness Br and the through image brightness Bf. Then, the arithmetic operation circuit 101 determines that the light is in the backlight state if Bf <Br, and determines that the light is in the backlight state if Br <Bf.

--- About brightness control of backlight 7b ---
When the power switch (not shown) of the camera 1 is turned on and the camera 1 is activated, the backlight with the brightness B is used as in the first embodiment until the brightness control of the backlight 7b described below is performed. 7b lights up.

(1) When the surroundings are bright (when the ambient light source is strong)
(1-1) Backlight State As described above, when the light from the ambient light source is strong and the backlight is in the backlight state, the visibility of the display monitor 7 is lowered by the ambient light source. Therefore, the arithmetic circuit 101 determines whether or not the intensity of the ambient light from the light source is so strong as to adversely affect the visibility of the display monitor 7. Specifically, the arithmetic circuit 101 is so strong that the intensity of light from the ambient light source adversely affects the visibility of the display monitor 7 if the detected back surface brightness Br exceeds a predetermined brightness b2. Judge.

  If the arithmetic circuit 101 determines that the detected backlight luminance Br exceeds the predetermined luminance b2 and is in the backlight state as described above, the backlight 7b is turned on at a luminance C higher than the normal luminance B. The backlight driving unit 162 is controlled so as to do so. That is, when the arithmetic circuit 101 determines that the backlight state is in the backlight state as described above when the detected back surface brightness Br exceeds the predetermined brightness b2, the arithmetic circuit 101 changes the brightness level of the backlight 7b to the brightness C. The backlight driving unit 162 is controlled. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance C. As a result, the brightness of the display screen of the display monitor 7 increases, so that the visibility of the display monitor 7 is improved.

(1-2) Forward light state As described above, in the forward light state, display is performed even when the intensity of light from the ambient light source is strong enough to adversely affect the visibility of the display monitor 7 in the backlight state. The visibility of the monitor 7 does not deteriorate so much. Accordingly, when the arithmetic circuit 101 determines that the detected backlight luminance Br exceeds the predetermined luminance b2 and is in the following light state as described above, the detected rear luminance Br is higher than the luminance b2. It is determined whether or not a predetermined luminance b3 is exceeded.

  When the arithmetic circuit 101 determines that the detected rear luminance Br exceeds the predetermined luminance b3 and is in the following light state as described above, the backlight driving unit 162 causes the backlight 7b to be lit at the luminance C. To control. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance C. As a result, the brightness of the display screen of the display monitor 7 increases, so that the visibility of the display monitor 7 is improved.

  Even if the arithmetic circuit 101 determines that the detected rear luminance Br exceeds the predetermined luminance b2 and is in the following light state as described above, the detected rear luminance Br is equal to or lower than the predetermined luminance b3. Is determined, the backlight drive unit 162 is controlled so that the backlight 7b is lit at the luminance B. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance B. As a result, the brightness of the display screen of the display monitor 7 is the same as the normal state. However, as described above, the visibility of the display monitor 7 is not deteriorated by the light from the ambient light source. The image displayed on the monitor 7 can be visually recognized with certainty.

(2) When the surroundings are reasonably bright (when the light from the ambient light source is not so strong)
When the intensity of the light from the ambient light source is not so strong as to adversely affect the visibility of the display monitor 7, that is, when the detected rear luminance Br is equal to or lower than the predetermined luminance b2, the display monitor 7 It is not necessary to increase the luminance of the backlight 7b in order to improve the visibility of the backlight 7b. Therefore, when the arithmetic circuit 101 determines that the detected back surface brightness Br is equal to or lower than the predetermined brightness b2, the arithmetic circuit 101 controls the backlight driving unit 162 so that the backlight 7b is turned on at the brightness B. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance B. As a result, the brightness of the display screen of the display monitor 7 is the same as the normal state. However, as described above, the visibility of the display monitor 7 is not deteriorated by the light from the ambient light source. The image displayed on the monitor 7 can be visually recognized with certainty.

(3) When the surroundings are dark (when the light from the ambient light source is weak)
Note that when the light from the ambient light source is weak and the surroundings are dark, the photographer's eyes adapt to the darkness. Therefore, even if the brightness of the display screen of the display monitor 7 is lowered than the normal state, the visibility is low. Will not drop. Also, from the viewpoint of power saving, it is desirable to lower the brightness of the display screen of the display monitor 7 from the normal state. Conversely, if the brightness of the display screen of the display monitor 7 is the same as the normal state, the photographer The display monitor 7 may feel dazzling.

  Therefore, when the arithmetic circuit 101 determines that the detected rear luminance Br is equal to or lower than the predetermined luminance b1 lower than the luminance b2, the backlight 7b is turned on at the luminance A lower than the luminance B. The drive unit 162 is controlled. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance A. As a result, the brightness of the display screen of the display monitor 7 is lower than that in the normal state. However, as described above, since the photographer's eyes adapt to darkness, the visibility of the display monitor 7 does not deteriorate.

  Note that, for the same reason as in the first embodiment, it is desirable to appropriately change the values of the luminances b1 to b3 described above. Therefore, in the camera 1 of the present embodiment, the arithmetic circuit 101 estimates the color temperature of the ambient light based on the through image obtained by imaging with the imaging element 202. Based on the estimated color temperature, the arithmetic circuit 101 reads the values of the luminances b1 to b3 as appropriate from a map of the luminance b1 to b3 values stored in advance, and uses them for the luminance control of the backlight 7b described above. Set as values of luminance b1 to b3. Therefore, when the brightness control of the backlight 7b described above is performed, the determination is made based on the brightness b1 to b3 set according to the color temperature of the ambient light. It can be said that the luminances b1 to b3 described above are threshold values of the brightness around the camera 1 regarding the visibility of the display monitor 7.

--- Timing of luminance change of backlight 7b ---
As in the first embodiment, the camera 1 of the present embodiment is configured such that when the release button 2 is half-pressed, the luminance of the display monitor 7 is changed as described above.

--- Flow chart ---
FIG. 11 is a flowchart showing the processing contents of a program for performing the luminance change processing of the backlight 7b described above. After the power switch (not shown) is turned on, every time the release button 2 is pressed halfway and a half-press operation signal is received from the release switch 141, a program for performing this processing is started and the arithmetic circuit 101 Executed.

  In step S31, the value of the back surface brightness Br and the value of the through image brightness Bf are read, and the process proceeds to step S33. In step S33, the color temperature of the ambient light is estimated based on the through image signal from the image sensor 202, and the process proceeds to step S35. In step S35, based on the color temperature of the ambient light estimated in step S33, the values of luminance b1 to b3 are read from the previously stored luminance b1 to b3 value map, and the luminance b1 to b3 used for the following determinations. And proceed to step S37.

  In step S37, it is determined whether the back surface brightness Br read in step S31 is lower than the brightness b1 set in step S35. If a negative determination is made in step S37, the process proceeds to step S39, and it is determined whether the back surface brightness Br read in step S31 is lower than the brightness b2 set in step S35. If a negative determination is made in step S39, the process proceeds to step S41, and it is determined whether or not the back surface brightness Br read in step S31 is lower than the through image brightness Bf read in step S31.

  If the determination in step S41 is affirmative, that is, if it is determined that the light is backlit, the process proceeds to step S43, and the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance C, and the process is terminated. . If the determination in step S41 is negative, that is, if it is determined that the light is direct light, the process proceeds to step S45, and it is determined whether or not the back surface brightness Br read in step S31 is higher than the brightness b3 set in step S35. If an affirmative determination is made in step S45, the process proceeds to step S47, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance C, and the process is terminated.

  If a negative determination is made in step S45, the process proceeds to step S49, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance B, and the process is terminated.

  If an affirmative determination is made in step S39, the process proceeds to step S51, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance B, and the process is terminated.

  If an affirmative determination is made in step S37, the process proceeds to step S53, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance A, and the process is terminated.

In the camera 1 of the second embodiment described above, the following functions and effects are provided in addition to the functions and effects of the first embodiment.
(1) The luminance level of the backlight 7b is set based on the value of the back surface luminance Br measured by the photometric sensor 253 and the value of the through image luminance Bf obtained by the image sensor 202. Thereby, since the structure of the photometry sensor 253 can be made simpler, an increase in cost can be suppressed.

--- Third embodiment ---
A third embodiment of the camera according to the present invention will be described with reference to FIGS. In the following description, the same components as those in the first and second embodiments are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first and second embodiments. In the present embodiment, mainly by performing face recognition of a subject based on a through image from the image sensor 202 and comparing the brightness of the recognized face area with the brightness of the surrounding area, backlighting is performed. It differs from the first and second embodiments in that it is determined whether or not it is in a state.

  The block diagram for explaining the configuration of the camera 1 of the third embodiment is the same as the block diagram of the camera 1 of the second embodiment. That is, the camera 1 of the third embodiment is provided with a photometric sensor 253 that measures the luminance of the entire back surface of the camera 1 instead of the photometric sensor 153.

--- Judgment of direct light condition and backlight condition ---
FIG. 12 shows an example of a through image obtained by imaging with the image sensor 202. In this through image 301, for example, one person 302 is shown as a subject. As shown in FIG. 3, when the light is in the normal light state, the ambient light source is located behind the photographer. Therefore, the difference between the luminance of the face portion 302a of the subject (person 302) shown in FIG. 12 and the luminance of the area 303 around the face portion 302a is reduced. Also, as shown in FIG. 4, in the backlight state, the ambient light source is positioned in front of the photographer. Therefore, the brightness of the face portion 302 a of the person 302 is lower than the brightness of the surrounding area 303. In addition, the absolute value of the difference between the brightness of the face portion 302a and the brightness of the surrounding area 303 is larger than that in the follow light state.

  Therefore, in the camera 1 of the present embodiment, the arithmetic circuit 101 determines the presence or absence of the face portion 302a of the person 302 from the through image 301 obtained by imaging with the imaging element 202. Since the technique of face recognition processing for determining the presence or absence of the face portion 302a of the person 302 from the through image 301 is well known, the description thereof is omitted. When it is determined that the human face portion 302a exists, the arithmetic circuit 101 compares the brightness of the face portion 302a with the brightness of the surrounding area 303.

  The arithmetic circuit 101 has a luminance of the face portion 302a lower than that of the surrounding region 303, and an absolute value of a difference between the luminance of the face portion 302a and the luminance of the surrounding region 303 is determined from a predetermined value Δb. Is larger, it is determined that the backlight is in the backlit state. The arithmetic circuit 101 also determines that the absolute value of the difference between the brightness of the face portion 302a and the brightness of the surrounding area 303 is greater than the value Δb when the brightness of the face portion 302a is higher than the brightness of the surrounding area 303. If it is smaller, it is determined that the light is in a follow-up state.

--- About brightness control of backlight 7b ---
When the power switch (not shown) of the camera 1 is turned on and the camera 1 is activated, the luminance B is the same as in the first and second embodiments until the luminance control of the backlight 7b described below is performed. The backlight 7b is turned on.

(1) When the surroundings are bright (when the ambient light source is strong)
(1-1) Backlight State As described above, when the light from the ambient light source is strong and the backlight is in the backlight state, the visibility of the display monitor 7 is lowered by the ambient light source. Therefore, the arithmetic circuit 101 determines whether or not the intensity of the ambient light from the light source is so strong as to adversely affect the visibility of the display monitor 7. Specifically, the arithmetic circuit 101 is so strong that the intensity of light from the ambient light source adversely affects the visibility of the display monitor 7 if the detected back surface brightness Br exceeds a predetermined brightness b2. Judge.

  When the detected back surface luminance Br exceeds the predetermined luminance b2, the arithmetic circuit 101 specifies the face portion 302a of the person 302 from the through image 301 obtained by imaging with the image sensor 202, and as described above. It is determined whether or not the backlight is in the backlit state. If the arithmetic circuit 101 determines that the backlight is in the backlight state, the arithmetic circuit 101 controls the backlight driving unit 162 so that the backlight 7b is lit at a luminance C higher than the normal luminance B. That is, when the arithmetic circuit 101 determines that the backlight state is in the backlight state as described above when the detected back surface brightness Br exceeds the predetermined brightness b2, the arithmetic circuit 101 changes the brightness level of the backlight 7b to the brightness C. The backlight driving unit 162 is controlled. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance C. As a result, the brightness of the display screen of the display monitor 7 increases, so that the visibility of the display monitor 7 is improved.

(1-2) Forward light state As described above, in the forward light state, display is performed even when the intensity of light from the ambient light source is strong enough to adversely affect the visibility of the display monitor 7 in the backlight state. The visibility of the monitor 7 does not deteriorate so much. Accordingly, when the arithmetic circuit 101 determines that the light is in the follow-up state as described above when the detected back surface brightness Br exceeds the predetermined brightness b2, the brightness of the surrounding area 303 is set to a predetermined brightness. It is determined whether or not c is exceeded.

  The arithmetic circuit 101 determines that the detected back surface brightness Br exceeds the predetermined brightness b2 and is in the following light state as described above, and the brightness c of the surrounding area 303 is determined in advance. If it is determined that the luminance exceeds the value, the backlight driving unit 162 is controlled so that the backlight 7b is lit at the luminance C. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance C. As a result, the brightness of the display screen of the display monitor 7 increases, so that the visibility of the display monitor 7 is improved.

  Note that even if the arithmetic circuit 101 determines that the detected rear luminance Br exceeds the predetermined luminance b2 and is in the following light state as described above, the luminance of the surrounding area 303 exceeds the luminance c. If it is determined that the backlight 7b does not exist, the backlight driving unit 162 is controlled so that the backlight 7b is turned on at the luminance B. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance B. As a result, the brightness of the display screen of the display monitor 7 is the same as the normal state. However, as described above, the visibility of the display monitor 7 is not deteriorated by the light from the ambient light source. The image displayed on the monitor 7 can be visually recognized with certainty.

(1-3) When Face Recognition is Unsuccessful There may be a case where no person exists in the live view, or a person's face in the live view cannot be recognized for some reason. Therefore, if the detected back surface brightness Br exceeds the predetermined brightness b2 and the face cannot be recognized, the arithmetic circuit 101 is in a backlight state as in the second embodiment. It is determined whether the light is in a follow-up state. That is, the arithmetic circuit 101 compares the magnitude relationship between the back surface brightness Br and the through image brightness Bf. Then, the arithmetic operation circuit 101 determines that the light is in the backlight state if Bf <Br, and determines that the light is in the backlight state if Br <Bf.

  When the arithmetic circuit 101 determines that the backlight state is in the backlight state as described above based on the back surface brightness Br and the through image brightness Bf when the back surface brightness Br exceeds the predetermined brightness b2, the arithmetic circuit 101 determines that the back light brightness Br is higher than the normal brightness B. The backlight driving unit 162 is controlled so that the backlight 7b is lit with high luminance C. On the other hand, when the arithmetic circuit 101 determines that the rear luminance Br exceeds the predetermined luminance b3 and is in the following light state as described above based on the rear luminance Br and the through image luminance Bf, the arithmetic circuit 101 performs backlighting with the luminance C. The backlight drive unit 162 is controlled so that 7b is lit.

  If the arithmetic circuit 101 determines that the detected back surface brightness Br is greater than or equal to the brightness b3 even if it exceeds the predetermined brightness b2 and is in the follow-up state as described above, the backlight 7b with the brightness B is used. The backlight driving unit 162 is controlled so as to light up.

(2) When the surroundings are reasonably bright (when the light from the ambient light source is not so strong)
When the arithmetic circuit 101 determines that the detected rear luminance Br is equal to or lower than the predetermined luminance b2, the arithmetic circuit 101 causes the backlight 7b to be lit at the luminance B as in the second embodiment. The drive unit 162 is controlled.

(3) When the surroundings are dark (when the light from the ambient light source is weak)
If the arithmetic circuit 101 determines that the detected back surface brightness Br is equal to or lower than the predetermined brightness b1 lower than the brightness b2, the brightness lower than the brightness B is the same as in the second embodiment. The backlight drive unit 162 is controlled so that the backlight 7b is turned on at A. The backlight driving unit 162 drives the backlight 7b so as to be lit at the luminance A.

--- Flow chart ---
FIG. 13 is a flowchart showing the processing contents of a program for performing the luminance change processing of the backlight 7b described above. After the power switch (not shown) is turned on, every time the release button 2 is pressed halfway and a half-press operation signal is received from the release switch 141, a program for performing this processing is started and the arithmetic circuit 101 Executed.

  From step S31 to step S39, step S51 and step S53 are the same as those in the second embodiment.

  If a negative determination is made in step S39, the process proceeds to step S141a, a known face recognition process is performed based on the through image from the image sensor 202, and the process proceeds to step S141b. In step S141b, it is determined whether or not face recognition has been performed by the face recognition processing in step S141a. If an affirmative determination is made in step S141b, the process proceeds to step S141c, and it is determined whether the backlight is in the backlit state as described above based on the brightness of the face portion 302a and the brightness of the surrounding area 303. If a positive determination is made in step S141c, the process proceeds to step S43. The processing after step S43 is the same as that of the second embodiment.

  If a negative determination is made in step S141c, the process proceeds to step S145, and whether or not the surrounding brightness of the person's face in the through image is bright, that is, the brightness of the surrounding area 303 exceeds a predetermined brightness c. Determine whether or not. If a positive determination is made in step S145, the process proceeds to step S47, and if a negative determination is made in step S145, the process proceeds to step S49. The processes after step S47 and step S49 are the same as those in the second embodiment.

  If a negative determination is made in step S141b, the process proceeds to step S41. The processing after step S41 is the same as that in the second embodiment.

The camera 1 according to the third embodiment described above has the following effects in addition to the effects of the first and second embodiments.
(1) A person's face part is specified from the through image obtained by imaging with the image sensor 202, and the brightness of the face part is compared with the brightness of the surrounding area to determine whether or not it is in a backlight state. Configured to judge. As a result, the accuracy of determining whether or not the backlight is in the backlight state is improved, so that the luminance of the backlight 7b can be accurately controlled, and the visibility of the display monitor 7 can be ensured in various environments.

---- Modified example ---
(1) In the above description, the luminance a1 to a3 and the luminance b1 to b3 are changed according to the color temperature of the ambient light estimated from the through image, but the present invention is not limited to this. For example, the luminance a1 to a3 and the luminance b1 to b3 may be configured to be set to arbitrary values by the user. Moreover, you may comprise so that the brightness | luminance a1-a3 and the brightness | luminance b1-b3 may be changed according to imaging | photography mode. In this case, for example, there is a sea / snow mode that is set when shooting in a very bright environment such as the seaside or a slope, but when the shooting mode is set to the sea / snow mode, the arithmetic circuit 101 You may comprise so that the brightness | luminances a1-a3 and the brightness | luminances b1-b3 may be set to the same value as the case where the color temperature in the above-mentioned description is high. Also, for example, there is a sunset mode that is set at the time of shooting at sunset or sunset, but when the shooting mode is set to sunset mode, the arithmetic circuit 101 is the same as when the color temperature in the above description is low. You may comprise so that the brightness | luminance a1-a3 and the brightness | luminance b1-b3 may be set to a value.

  Furthermore, you may comprise so that the brightness | luminance a1-a3 and the brightness | luminance b1-b3 may be changed with time. In this case, for example, when the arithmetic circuit 101 receives a half-press operation signal from the release switch 141, the arithmetic circuit 101 reads time data from a clock built in the camera 1. The arithmetic circuit 101 determines whether or not the read time corresponds to a daytime period (for example, from 9 o'clock to 15 o'clock), or a morning or evening time period (for example, from 6 o'clock to 9 o'clock, or 15 It is judged whether it corresponds to from 18:00 to 18:00). The arithmetic circuit 101 sets the luminances a1 to a3 and the luminances b1 to b3 to the same values as when the color temperature is high in the above description when the read time falls in the daytime time zone. In addition, when the read time falls in the morning or evening time zone, the arithmetic circuit 101 sets the luminances a1 to a3 and the luminances b1 to b3 to the same values as when the color temperature in the above description is low. .

  The luminances a1 to a3 and the luminances b1 to b3 may be fixed to a constant value without being changed.

(2) In the first embodiment described above, the determination is made using the peripheral luminance Bb in each determination step of step S7, step S9, and step S15 in FIG. 9, but the present invention is not limited to this. For example, in each determination step of step S7, step S9, and step S15 in FIG. 9, the face luminance Ba may be used instead of the peripheral luminance Bb, and the through image luminance Bf described in the second embodiment is used. There may be the same operation effect as the operation effect mentioned above.

  In the second embodiment described above, the determination is made using the back surface brightness Br in each determination step of step S37, step S39, and step S45 of FIG. 11, but the present invention is not limited to this. For example, in each determination step of step S37, step S39, and step S45 in FIG. 11, the through image luminance Bf may be used instead of the back luminance Br, and the same operational effects as the above-described operational effects are achieved.

  Similarly, in the third embodiment described above, the through image brightness Bf may be used in place of the back brightness Br in each determination step of step S37, step S39, and step S45 in FIG. Has the same effect as the effect.

(3) In the first embodiment described above, the configuration is such that if the facial luminance Ba is higher than the peripheral luminance Bb, it is determined that the backlight is in the backlight state. However, the present invention is not limited to this. For example, when the shooting mode is set to the sunset mode, the backlight is considered to be a case where the elevation angle of the sun is small and a backlight state is likely to occur, regardless of the height relationship between the face luminance Ba and the peripheral luminance Bb. You may comprise so that it may judge that it is in a state.

  In this case, a flowchart showing the processing contents of the program for performing the luminance change processing of the backlight 7b is, for example, as shown in FIG. As shown in the flowchart of FIG. 14, step S10 is newly provided between step S9 and step S11 of the flowchart of FIG. 9 in the first embodiment. When step S9 is executed, the arithmetic operation circuit 101 proceeds to step S10, and determines whether or not the shooting mode of the camera 1 is set to the sunset mode. If a positive determination is made in step S10, the process proceeds to step S13, and if a negative determination is made in step S10, the process proceeds to step S11.

  If the shooting mode is set to the sunset mode and the through image brightness Bf obtained by the image sensor 202 is higher than a certain level, the backlight is used regardless of the surrounding brightness Bb detected by the photometric sensor 153. You may comprise so that the brightness | luminance of 7b may be raised.

  In this case, a flowchart showing the processing contents of the program for performing the luminance change processing of the backlight 7b is as shown in FIG. 15, for example. As shown in the flowchart of FIG. 15, steps S6a to S6d are newly provided on the flowchart of FIG. 9 in the first embodiment, and step S6a is inserted between steps S5 and S7. When step S5 is executed, the arithmetic operation circuit 101 proceeds to step S6a, and determines whether or not the shooting mode of the camera 1 is set to the sunset mode.

  If an affirmative determination is made in step S6a, the process proceeds to step S6b, the through image brightness Bf is read, and the process proceeds to step S6c. In step S6c, it is determined whether or not the through image brightness Bf read in step S6b is equal to or greater than a predetermined value. If an affirmative determination is made in step S6c, the process proceeds to step S6d, where the backlight driving unit 162 is controlled to change the luminance level of the backlight 7b to the luminance C, and the process is terminated.

  If a negative determination is made in step S6c, the process proceeds to step S7. If a negative determination is made in step S6a, the process proceeds to step S7.

(4) In the second embodiment described above, when the focal length of the imaging optical system is long, the ambient light source may be out of the imaging range even in a backlight state. Therefore, even in the backlight state, the back surface brightness Br does not necessarily decrease and the through image brightness Bf does not necessarily increase. Therefore, when the focal length of the imaging optical system is long, the luminance of the backlight 7b may be increased if the rear luminance Br is higher than the luminance b2.

  That is, the arithmetic circuit 101 reads the focal length of the imaging optical system and the back surface brightness Br. When the read focal length is equal to or greater than the predetermined focal length and the read back surface brightness Br is higher than the brightness b2, the arithmetic circuit 101 changes the brightness level of the backlight 7b to the brightness C. The write driver 162 is controlled.

(5) In the above description, when the arithmetic circuit 101 receives the half-pressing operation signal from the release switch 141, the program for performing the brightness changing process of the backlight 7b is started. Is not limited to this. For example, the arithmetic circuit 101 may be configured to start a program for performing a luminance change process of the backlight 7b when a power switch (not shown) is turned on. In this case, when the power switch is turned on, the luminance control of the backlight 7b described above is always performed regardless of whether the release button 2 is operated.

  Further, if a vibration sensor is newly provided in the camera body 10 and the output value of the vibration sensor is stabilized, it is assumed that the posture of the camera 1 has been determined (the shooting composition has been determined), and the arithmetic circuit 101 has the back. You may comprise so that the program which performs the luminance change process of the light 7b may be started. Furthermore, if a vertical / horizontal position sensor is newly provided and the output value of the vertical / horizontal position sensor is stabilized, it is considered that the photographing composition has been determined, and the arithmetic circuit 101 performs the luminance change processing of the backlight 7b. You may comprise so that a program may be started. In these cases, when the photographing composition is determined and the posture of the camera 1 is stabilized, the luminance control of the backlight 7b described above is performed.

  In addition, if the face recognition process described above is performed and it is determined that a face part is present in the through image, the arithmetic circuit 101 performs the brightness changing process of the backlight 7b, assuming that the image can be captured. You may comprise so that a program may be started.

(6) When determining whether or not the backlight is in the backlight state, the determination may be made based on the difference in luminance between the bright portion and the dark portion in the through image (luminance difference in the through image). For example, if the brightness difference in the through image is large, it may be determined that the ambient light source is in front of the camera 1 and is in the backlight state. When determining whether or not the backlight is in this way, if the focal length of the imaging optical system is long, the ambient light source may be out of the imaging range even in the backlight. . Therefore, even in the backlight state, the brightness difference in the through image is not necessarily increased. Accordingly, when the focal length of the imaging optical system is long, it may be configured to be regarded as being in a backlit state regardless of the brightness difference in the through image.

(7) In the above description, the display monitor 7 is a non-self-luminous liquid crystal display (LCD), but the present invention is not limited to this. For example, a self-luminous display device such as an organic EL or a field emission display (FED) may be used as the display monitor 7, and the same operational effects as the above-described operational effects can be obtained. When a self-luminous display device is used as the display monitor 7, the display brightness of the display device itself may be changed instead of the brightness of the backlight 7b.

(8) In the above description, the backlight 7b is turned on with the luminance C when it is determined that the backlight is in the backlighting state and when it is determined that the ambient light is more than a certain degree in the following light state. Although configured, the present invention is not limited to this. For example, the backlight 7b may be turned on with different brightness depending on whether it is determined that the backlight is in the backlighting state or if the ambient light is determined to be brighter than a certain level. Good. In any case, it is desirable that the backlight 7b is lit with a luminance higher than the luminance B described above.

(9) In the above description, the camera 1 has been described as an example of an electronic device having the display monitor 7. However, the present invention is not limited to the camera, and is a portable television, an image reproducing device, a mobile phone, a PDA, a notebook, and the like. The present invention can be applied to various electronic devices having a display device such as a PC.
(10) Each embodiment and modification described above may be combined.

  Note that the present invention is not limited to the above-described embodiment, and a display device provided in the housing, and a luminance distribution measuring unit that measures the luminance distribution in the direction in which the display surface of the display device is directed. The determination means for determining the height relationship between the luminance of the first area in the luminance distribution measured by the luminance distribution measuring means and the luminance of the second area around the first area, and display based on the determination result of the determination means The apparatus includes electronic devices having various structures including a luminance setting unit that sets the luminance value of the device and a display control unit that controls the display device so that the screen is displayed with the luminance value set by the luminance setting unit.

It is a perspective view of the camera of a 1st embodiment. 2 is a block diagram illustrating a configuration of a camera 1. FIG. It is a figure explaining a follow light state. It is a figure explaining a backlight state. 3 is a diagram conceptually showing the configuration of a photometric sensor 153. FIG. It is a figure which shows the shape of the photometry area of the detection element 153a. It is a figure which shows the positional relationship of the camera 1 and a photographer. It is a figure which shows the relationship between the brightness | luminance of a photometry area of the detection element 153a, a follow light state, and a backlight state. It is a flowchart which shows the processing content of the program which performs the luminance change process of the backlight 7b. It is a block diagram explaining the structure of the camera 1 of 2nd Embodiment and 3rd Embodiment. It is a flowchart which shows the processing content of the program which performs the luminance change process of the backlight 7b of 2nd Embodiment. 6 is a diagram illustrating an example of a through image obtained by imaging with an imaging element 202. FIG. It is a flowchart which shows the processing content of the program which performs the luminance change process of the backlight 7b of 3rd Embodiment. It is a figure which shows a modification. It is a figure which shows a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Camera 2 Release button 7 Display monitor 7b Backlight 101 Arithmetic circuit 135,235 Photometric sensor 153a Detection element 153b Lens 153c Central photometry area 153d Peripheral photometry area 141 Release switch 162 Backlight drive unit 202 Image sensor

Claims (22)

Imaging means for capturing a subject image;
A display device provided in the housing of the camera;
A luminance distribution measuring means for measuring a luminance distribution in a direction in which the display surface of the display device is directed;
Determining means for determining a height relationship between the brightness of the first area in the brightness distribution measured by the brightness distribution measuring means and the brightness of the second area around the first area;
Brightness setting means for setting a brightness value of the display device based on a determination result of the determination means;
A camera comprising: display control means for controlling the display device so that the screen is displayed with the brightness value set by the brightness setting means. The camera of claim 1,
The luminance setting unit sets the luminance value to a first value when the determination unit determines that the luminance of the first region is lower than the luminance of the second region, and the first region When the determination unit determines that the luminance of the second region is higher than the luminance of the second region, the luminance value is set to a second value larger than the first value. The camera according to claim 2,
The luminance setting means is configured such that, even when the determination means determines that the luminance of the first area is lower than the luminance of the second area, the luminance of the second area is determined based on a predetermined value. In the case of being high, the luminance value is set to a third value higher than the first value. The camera of claim 1,
It further comprises ambient brightness detection means for detecting brightness around the camera,
The brightness setting means sets the brightness value to the first value regardless of the determination by the determination means when the ambient brightness of the camera detected by the ambient brightness detection means is lower than a predetermined threshold. Or a fourth value lower than the first value,
The brightness setting means determines the brightness of the display device based on the determination result of the determination means when the ambient brightness of the camera detected by the ambient brightness detection means is higher than a predetermined threshold. A camera characterized by setting a value. The camera according to claim 4, wherein
A camera, further comprising a threshold value changing unit that changes the predetermined threshold value based on a user operation input. The camera according to claim 4, wherein
The ambient brightness detection means is the imaging means, and detects the ambient brightness of the camera based on the output of the imaging means. The camera according to claim 4, wherein
The ambient brightness detecting means is the brightness distribution measuring means, and the ambient brightness of the camera is based on at least one of the brightness of the first area and the brightness of the second area measured by the brightness distribution measuring means. A camera characterized by detecting the height. The camera of claim 1,
The camera according to claim 1, wherein the first area is a portion near the center of a measurement area measured by the luminance distribution measuring means. Imaging means for imaging a subject image on the front surface of the camera housing;
A display device provided on the back of the housing;
Back brightness detection means for detecting the brightness of the back;
A luminance value determining unit that determines a luminance value of the display device based on the output of the imaging unit and the brightness of the back surface detected by the back surface brightness detecting unit;
Brightness setting means for setting the brightness value of the display device to the brightness value determined by the brightness value determining means;
A camera comprising: display control means for controlling the display device so that the screen is displayed with the brightness value set by the brightness setting means. The camera according to claim 9, wherein
The luminance value determining unit determines whether the backlight is in a backlight state based on the output of the imaging unit and the brightness of the back surface detected by the back surface brightness detecting unit, and determines that the light is in a follow light state. Then, the brightness value is determined to be a first value, and if it is determined that the backlight is in a backlight state, the brightness value is determined to be a second value higher than the first value. . The camera of claim 10, wherein
The brightness value determining unit is configured to determine the back light brightness even when the brightness value determining unit determines that the light is in a follow light state based on the output of the imaging unit and the brightness of the back surface detected by the back surface brightness detecting unit. The camera according to claim 1, wherein when the brightness of the back surface detected by the detection means is brighter than a predetermined brightness, the luminance value is determined to be a third value higher than the first value. The camera according to claim 9, wherein
It further comprises ambient brightness detection means for detecting brightness around the camera,
When the brightness around the camera detected by the ambient brightness detection means is lower than a predetermined threshold, the brightness setting means does not depend on the determination of the brightness value determination means. Set the luminance value to the first value or a fourth value lower than the first value;
When the brightness around the camera detected by the ambient brightness detection means is higher than a predetermined threshold, the brightness setting means, based on the determination result of the brightness value determination means, the display device A camera characterized by setting the brightness value of the camera. The camera according to claim 12, wherein
A camera, further comprising a threshold value changing unit that changes the predetermined threshold value based on a user operation input. The camera according to claim 12, wherein
The ambient brightness detection means is the imaging means, and detects the ambient brightness of the camera based on the output of the imaging means. The camera according to claim 12, wherein
The ambient brightness detection means is the back brightness detection means, and detects the ambient brightness of the camera based on the brightness of the back surface detected by the back brightness detection means. . Imaging means for capturing a subject image;
A display device provided in the housing of the camera;
Face recognition means for recognizing a face portion of a person in the subject image based on the subject image captured by the imaging means;
A luminance value determining means for determining a luminance value of the display device based on a difference in brightness between an area of the face portion of the person recognized by the face recognition means and an area around the face portion;
Brightness setting means for setting the brightness value of the display device to the brightness value determined by the brightness value determining means;
A camera comprising: display control means for controlling the display device so that the screen is displayed with the brightness value set by the brightness setting means. The camera of claim 16, wherein
The luminance value determining unit determines whether or not the backlight unit is in a backlit state based on a difference in brightness between a region of the face portion of the person recognized by the face recognition unit and a region around the face portion. When it is determined that the light is in the follow light state, the luminance value is determined to be a first value. When it is determined that the light is in the backlight state, the luminance value is set to a second value higher than the first value. A camera characterized by being determined. The camera of claim 17,
The luminance value determining means is determined to be in a follow-up state based on a difference in brightness between the face portion area of the person recognized by the face recognition means and the surrounding area of the face portion. Even when the brightness of the area around the face recognized by the face recognition means is brighter than a predetermined brightness, the brightness value is set to be higher than the first value. A camera characterized by determining a value of 3. The camera of claim 16, wherein
It further comprises ambient brightness detection means for detecting brightness around the camera,
When the brightness around the camera detected by the ambient brightness detection means is lower than a predetermined threshold, the brightness setting means does not depend on the determination of the brightness value determination means. Set the luminance value to the first value or a fourth value lower than the first value;
When the brightness around the camera detected by the ambient brightness detection means is higher than a predetermined threshold, the brightness setting means, based on the determination result of the brightness value determination means, the display device A camera characterized by setting the brightness value of the camera. The camera of claim 19, wherein
A camera, further comprising a threshold value changing unit that changes the predetermined threshold value based on a user operation input. The camera of claim 19, wherein
The ambient brightness detection means is the imaging means, and detects the ambient brightness of the camera based on the output of the imaging means. A display device provided in a housing;
A luminance distribution measuring means for measuring a luminance distribution in a direction in which the display surface of the display device is directed;
Determining means for determining a height relationship between the brightness of the first area in the brightness distribution measured by the brightness distribution measuring means and the brightness of the second area around the first area;
Brightness setting means for setting a brightness value of the display device based on a determination result of the determination means;
An electronic apparatus comprising: display control means for controlling the display device so that the screen is displayed with the brightness value set by the brightness setting means.

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