Patent Publication Number: US-2007096024-A1

Title: Image-capturing apparatus

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
      This application claims priority to Japanese Patent Application No. 2005-313336 filed on Oct. 27, 2005, which is incorporated herein by reference in its entirety.  
     FIELD OF THE INVENTION  
      The present invention relates to an image-capturing apparatus, and more particularly to automatic determination of a scene for image capturing (hereinafter called a “photographic scene”).  
     BACKGROUND OF THE INVENTION  
      An image-capturing apparatus, such as a digital camera, or the like, has hitherto been equipped with a mode selection button which enables selection of macroscopic photographing or a photographic scene (or a photographing mode) such as a portrait, a sports scene, a landscape, and the like. The user manually operates the mode selection button according to a subject to be photographed, to thus make settings. The digital camera controls exposure, white balance, and shutter speed according to the photographic scene (or the photographing mode) set by the user, thereby capturing an image of the subject.  
      In view that the user must perform intricate operations to manually select a photographic scene, there have been proposed techniques by means of which a digital camera automatically determines a photographic scene to a certain extent to thus capture the thus-determined photographic scene.  
      For instance, Japanese Patent Laid-Open Publication No. 2003-344891 describes a technique for ascertaining whether or not a subject includes a face and automatically setting a photographing mode of a camera according to a result of ascertainment. When a human face has been detected and a scaling factor for photographing is a given value or less, the photographing mode is set to a normal mode. When the scaling factor is greater than the given value, the photographing mode is set to a portrait mode. When the human face is not detected, a distance to the subject is a given value or greater, and it is nighttime, the photographing mode is set to a night view mode. If it is not nighttime, the photographing mode is set to a landscape mode or the like.  
      Japanese Patent Laid-Open Publication No. Hei-8-136971 describes that a camera is equipped with an infrared sensor; that an area of body temperature (hereinafter simply called a “body-temperature area”) showing the temperature of a body is extracted; and that exposure and a focal point are determined in accordance with a photometric value acquired in the body-temperature range and a measured distance to the body-temperature area.  
      As mentioned above, a technique for automatically determining a photographic scene on the basis of some pieces of information has heretofore been available. However, it is hard to say that various photographic scenes can be determined without fail. For example, even when a human face is not detected, a distance to the subject is a given distance or greater, and it is not nighttime, an actual photographic scene is a scene of a beach or a scene of snowy mountains. If these scenes are indiscriminately determined to belong to a landscape mode, acquisition of a high-quality image cannot be expected.  
      Japanese Patent Laid-Open Publication No. Hei-8-136971 describes acquisition of temperature information by means of the infrared sensor. However, this technique is confined to detection of the body-temperature area, and determination of a scene is not taken into account.  
      The present invention provides an image-capturing apparatus which enables enhanced accuracy of determination of a scene and easy acquisition of a higher-quality image.  
     SUMMARY OF THE INVENTION  
      The present invention provides an image-capturing apparatus comprising:  
      temperature detection means for detecting a temperature of a field;  
      image acquisition means for acquiring an image signal pertaining to the field;  
      image-processing means for detecting image characteristic information, such as a hue, saturation, luminance, a distance, movements, and the like, from the image signal obtained by the image acquisition means; and  
      determination means for determining which one of a plurality of photographic scenes corresponds to the field, on the basis of a combination of the temperature information about the field detected by the temperature detection means and the image characteristic information detected by the image-processing means.  
      In the present invention, a photographic scene can be automatically determined with high accuracy by means of a combination of the temperature of a field with image characteristic information, such as movements, a hue, saturation, luminance, and the like, of an image. Consequently, photographing conditions can be adjusted according to a scene to be determined. The user can acquire a high-quality image according to a scene by means of merely orienting the image-capturing apparatus to the field and capturing an image.  
      The invention will be more clearly comprehended by reference to the embodiments provided below. However, the scope of the invention is not limited to the embodiments.  
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
      Preferred embodiments of the present invention will be described in detail with reference to the following figures, wherein:  
       FIG. 1  is a block diagram of a digital camera according to a first embodiment of the present invention;  
       FIG. 2  is an overall processing flowchart of the embodiment;  
       FIG. 3  is a detailed flowchart of temperature characteristic detection processing in the embodiment;  
       FIG. 4A  is a descriptive view of temperature characteristics of a beach;  
       FIG. 4B  is a descriptive view of temperature characteristics of a snowy mountain;  
       FIG. 5  is a descriptive view of categories (patterns) used in processing for detecting characteristics of an image;  
       FIG. 6  is a detailed flowchart of processing for determining a scene (a photographing mode);  
       FIG. 7  is a descriptive view of a table used in processing for determining a scene;  
       FIG. 8  is a descriptive view of a table used in photographic control based on a determined scene;  
       FIG. 9  is a descriptive view of a category used for detecting temperature characteristics in another embodiment;  
       FIG. 10  is a descriptive view of a table used in processing for determining a scene in another embodiment;  
       FIG. 11  is a descriptive view of a table used in photographic control based on a determined scene; and  
       FIG. 12  is a descriptive view of temperature characteristic detection in yet another embodiment, showing a descriptive view of temperature characteristic detection achieved when only a body temperature is taken as an object. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
     First Embodiment  
       FIG. 1  shows a block diagram of a digital camera according to a first embodiment of the present invention. An optical system  10  including a group of lenses, a shutter, a diaphragm, and the like, gathers light of a field and guides the thus-gathered light to an image-capturing element  12 . Opening and closing of the shutter is controlled by a shutter control circuit  30 , and a diaphragm is controlled by a diaphragm motor control circuit  32 . A focus lens of the group of lenses is controlled by a focus motor control circuit  34 .  
      The image-capturing element  12  converts light of the field into an electrical signal, to thus generate an image signal. The image-capturing element  12  includes a known Bayer-arrangement color filter. The image signal is converted into a digital signal by means of an analog-to-digital circuit  7 , and the digital signal is supplied to a CPU  28 . The digital signal is further supplied from the CPU  28  to an image characteristic extraction circuit  18 . The image signal supplied to the CPU  28  is subjected to image processing such as white balance adjustment, edge enhancement processing, and the like. The thus-processed image signal is displayed on a color LCD  38 . Further, the processed image is converted into a JPEG format or a RAW format in response to operation of a release button, and the thus-converted image is stored as a captured image externally or in built-in memory  36 . Driving of the image-capturing element  12  is controlled by an image-capturing element drive circuit  16 .  
      In the meantime, the light having entered the optical system  10  is bifurcated by a half mirror  11 , and one of the thus-bifurcated beams enters an AF (autofocus) sensor  9 . A sensor signal output by the AF sensor  9  is processed by an A/F sensor processing circuit  14 , to thus compute a distance to the subject by means of, e.g., a phase detection method. The subject distance information is supplied to the CPU  28 . The other of the beams bifurcated by the half mirror  11  is converted into an electrical signal by means of a temperature sensor  8 , and the electrical signal is converted into a digital signal by means of an analog-to-digital circuit  6 . The thus-converted digital signal is supplied to the CPU  28 . The temperature sensor  8  is, e.g., a radiation thermometer. The radiation thermometer utilizes the phenomenon that all objects radiate heat in the form of electromagnetic waves. A temperature can be detected from a wavelength distribution of thermal radiation energy and the intensity of each of wavelengths. In accordance with a command from the CPU  28 , the temperature sensor  8  is controlled by a temperature sensor control circuit  22 , and the detected temperature of the field is supplied from the CPU  28  to a temperature-based information characteristic extraction circuit  24 . Alternatively, the temperature of the field may also be detected by means of a sensor for detecting the temperature of a field other than the temperature sensor  8 ; e.g., a two-dimensional image sensor for detecting infrared radiation. A technique for detecting the temperature distribution of a two-dimensional image has already been known as a thermography technique, an infrared thermography technique, or the like. All of the thus-detected temperatures are supplied to the temperature-based information characteristic extraction circuit  24  by way of the CPU  28 .  
      Temperature data pertaining to the field, which have been detected by the temperature sensor  8  or another sensor, are input to the temperature-based information characteristic extraction circuit  24 , where the characteristic of the temperature distribution of the field is detected. Specifically, the temperature-based information characteristic extraction circuit  24  divides a two-dimensional field image into a plurality of blocks, and classifies temperature distributions of the respective blocks into any of a plurality of predetermined temperature categories, thereby characterizing the temperature distributions. The temperature categories are arbitrary. However, the temperature categories can be classified into three categories; e.g., “body temperature,” “high temperature,” and “low temperature.” Temperatures detected by the temperature sensor  8 , or the like, are classified into any of the three categories. The body temperature is an example human temperature. A magnitude correlation among the temperatures is defined as high temperature&gt;body temperature&gt;low temperature. A classification method includes, for example, setting two threshold temperatures T 1 , T 2  (T 1 &gt;T 2 ); computing a typical temperature of each of the blocks from the temperatures detected by the temperature sensor  8  or the like (a typical temperature is computed by means of averaging, e.g., temperature distributions of the respective blocks); and comparing the typical temperature with the threshold temperatures T 1 , T 2 . When the typical temperature T exhibits a relationship of T&gt;T 1 , the block is classified into the “high temperature” category. When the typical temperature T exhibits a relationship of T 1 &gt;T&gt;T 2 , the block is classified into the “body temperature” category. When the typical temperature T exhibits a relationship of T&lt;T 2 , the block is classified into the “low temperature” category. The result of classification is supplied to a scene determination circuit  26 .  
      The image characteristic extraction circuit  18  processes the field image input by the CPU  28 , to thus detect image characteristic information such as a hue, saturation, a luminance, movements, and the like. The subject distance detected by the AF sensor control section  14  is input to the image characteristic extraction circuit  18 , and the detected values are classified into any of a plurality of categories. For instance, a hue of the image characteristic information is classified as “red,” “blue,” or the like, in accordance with a color histogram. The saturation of the image characteristic information is classified into any of “low saturation” and “high saturation” categories. The distance of the image characteristic information is classified into any one of a “near distance,” a “middle distance,” a “long distance,” or the like. An image is divided into a plurality of blocks, and classification is carried out on a per-block basis. The blocks subjected to the image characteristic extraction circuit  18  may be identical with or different from the blocks subjected to the temperature-based information characteristic extraction circuit  24 . For instance, the blocks subjected to the image characteristic extraction circuit  18  are broken into pieces which are smaller than the blocks subjected to the temperature-based information characteristic extraction circuit  24 . The result of classification is supplied to the scene determination section  26 .  
      The result of classification output from the temperature-based information characteristic extraction circuit  24  and the result of classification output from the image characteristic extraction circuit  18  are input to the scene determination circuit  26 , whereby a scene of the field is determined on the basis of these results. The scene to be determined in the present embodiment includes a portrait (Portrait) scene, a sports (Sports) scene, a beach (Beach) scene, a snow (Snow) scene, and a landscape (Landscape) scene. The thus-determined scene becomes a photographing mode of the digital camera. The result of determination of a scene is supplied to the CPU  28 .  
      The CPU  28  controls individual sections of the digital camera; supplies a control signal to at least any one of the shutter control circuit  30 , the diaphragm motor control circuit  32 , and the focus motor control circuit  34  according to, especially, a determined scene; and controls exposure, a shutter speed, and white balance, which are photographic conditions employed during photographing action. The CPU  28  controls edge processing of a captured image to thus determine whether the sharpness of the captured image is set to hard (an enhanced edge) or soft (a smooth edge). More specifically, a program which specifies control specifics for respective determined scenes has been stored as a firmware in ROM in advance, and control responsive to the determined scene is performed in accordance with the firmware. For instance, when the determined scene is a beach (Beach), the CPU  28  supplies a control signal to the diaphragm motor control circuit  32  to thereby control exposure in such a way that exposure, which is slightly higher than appropriate exposure, is achieved. When the determined scene is a landscape (Landscape), the CPU  28  supplies a control signal to the diaphragm motor control circuit  32  to thus control exposure in order to capture an image at the highest possible diaphragm setting.  
      Each of the temperature-based information characteristic extraction circuit  24 , the image characteristic extraction circuit  18 , and the scene determination circuit  26 , all of which are shown in  FIG. 1 , is formed from a microprocessor. However, some of these circuits may be formed from a common microprocessor.  
       FIG. 2  shows an overall processing flowchart of the present embodiment. When the power of the digital camera is activated, the temperature sensor  8  acquires temperature information about the field (S 101 ), and the temperature-based information characteristic extraction circuit  24  detects the characteristic of a temperature (S 102 ). Namely, the temperature-based information characteristic extraction circuit  24  classifies the temperatures of the respective blocks of the two-dimensional image of the field into any of a plurality of temperature categories, to thus detect the characteristic of the temperature of the field. Next, the image of the field is captured by the image-capturing element  12  (S 103 ), and the image characteristic extraction circuit  18  detects a characteristic of the image (S 104 ). The image characteristic extraction circuit  18  classifies the hue, the saturation, the movements, the distance, and the like, of the two-dimensional image pertaining to the field into any of the plurality of categories, thereby detecting the characteristic of the image. After detection of the characteristic of the temperature and the characteristic of the image, the scene determination circuit  26  determines a photographic scene of the field (S 105 ). Finally, the CPU  28  effects image-capturing operation by means of changing the photographic conditions and image parameters in accordance with the determined scene (S 106 ).  
      Respective processing operations will be described in detail hereunder.  
       FIG. 3  is a detailed flowchart of processing pertaining to S 102  shown in  FIG. 2 ; namely, processing for extracting temperature characteristics of a field. The temperature-based information characteristic extraction circuit  24  divides the range of a field image, which is an object to be detected by the temperature sensor  8 , into a plurality of blocks (S 1021 ). For instance, the range of the field image is divided into six blocks. Next, the typical temperature is computed on a per-block basis, and a determination is made as to whether or not the thus-computed typical temperature corresponds to the “body temperature” (S 1022 ). This determination is performed by means of comparing the typical temperature with the threshold temperatures T 1 , T 2  as mentioned above. When the typical temperature is determined to be “body temperature,” a flag TM showing “body temperature” is set in that block (S 1023 ). Meanwhile, when the typical temperature is not “body temperature,” a determination is then made as to whether or not the typical temperature corresponds to “high temperature” (S 1024 ). This determination is also made by means of comparing the typical temperature with the threshold temperatures T 1 , T 2 . When the typical temperature corresponds to “high temperature,” a flag TH showing “high temperature” is set in that block (S 1025 ). When the typical temperature corresponds to neither “body temperature” nor “high temperature,” a flag TL showing “low temperature” is set in the block (S 1026 ). All of the blocks are repeatedly subjected to the above-mentioned classification processing (S 1027 ).  
       FIGS. 4A and 4B  show results acquired as a result of different fields being subjected to temperature characteristic extraction.  FIG. 4A  shows a result acquired when the field is a beach, and  FIG. 4B  shows a result acquired when the field is a snowy mountain. White sands of a beach and snow surfaces of a snowy mountain look analogous in terms of a hue and saturation when viewed with the human eye, but may show a clear difference in temperature. As shown in  FIG. 4A , an upper portion of a screen of the beach is classified into the category TL, but a lower portion of the same is classified into the category TH. As shown in  FIG. 4B , an upper portion and a lower portion, both of which pertain to a screen of the snowy mountain, are classified into the category TL. For these reasons, the white sands of the beach and the white snow surfaces of the snowy mountain can be discriminated from each other as a result of use of the temperature characteristics.  
       FIG. 5  shows categories used in processing pertaining to S 104  shown in  FIG. 2 ; namely, processing for extracting characteristics of an image. The image characteristic extraction circuit  18  processes the image signal obtained by the image-capturing element  12  to thus detect movements, a hue, saturation, luminance, and the like; and classifies the detected movements into any of categories such as those shown in  FIG. 5 . Movements are classified into any of “partial,” “overall,” and “surrounding” categories. Movements can be detected by means of computing a difference between frames which differ from each other in terms of time. More specifically, the essential requirement is to move a frame of a block F(n- 1 ), which is a precedent block in terms of time, vertically and horizontally within a specified width; and to detect, as a motion vector, a direction (dx, dy) which realizes a minimum total difference between the frame of the precedent block and a frame F(n) of a block subsequent in terms of time; i.e.,  
       D   =     ∑     ∑                  F   ⁡     (   n   )       ⁢     (     Xi   ,   Yi     )       -       F   ⁡     (     n   -   1     )       ⁢     (   X   )     ⁢   i     +   dx     ,     Yi   +   dy            .             
 
 Although the amount and direction of movement are detected by means of a motion vector, in the present embodiment attention is paid particularly to the amount of movement and the position of the motion vector. When the thus-detected movement is present in only a portion of the field, the movement is classified into the “partial” category. When the movement is present in the entire field, the movement is classified into the “overall” category. When the movement is present in only the surroundings of the field, the movement is classified into the “surrounding” category. A skin color is included in hue, but in the present embodiment is assumed to be detected separately from hue. The thus-detected skin color is characterized by “area,” “roundness,” and “frequency of appearance.” Here, the term “area” signifies an area occupied by pixels in a detected single skin color region. The term “roundness” signifies the degree of similarity achieved when an occupied area in the detected single skin color region is analogous to a circle. These terms may be expressed by numerals or geometrical categories. 
 
      The area is classified into “large,” “middle,” and “small” categories. The roundness is classified into “circle,” “oval,” and “rectangular” categories. The frequency of appearance is classified into “high,” “intermediate,” and “low” categories. Hue is classified by a color histogram. Saturation is classified into “low saturation” and “high saturation.” A color temperature is classified into “low,” “intermediate,” and “high” categories. For instance, a color temperature of 400 klv or less is classified into the “low” category. A color temperature from 4000 klv to 6500 klv is classified into the “intermediate” category. A color temperature of 6500 klv or more is classified into the “high” category. Luminance is classified into “low,” “intermediate,” and “high” categories. For instance, a luminance of LV 8  or less is classified into the “low” category. A luminance of LV 8  to LV 12  is classified into the “middle” category. A luminance of LV 12  or more is classified into the “high” category. A distance to the subject is classified into “short,” “middle,” and “long.” For instance, a distance of 1.0 m or less is classified into the “short” category. A distance from 1.0 m to 10.0 m is classified into the “middle” category. A distance of 10.0 m or more is classified into the “long” category. As in the case of temperature, the result of classification is expressed by setting a predetermined flag to the respective blocks.  
       FIG. 6  shows a detailed flowchart of processing pertaining to S 105  shown in  FIG. 2 ; namely, processing for determining a scene.  FIG. 7  shows a table used for determining a scene. The table shown in  FIG. 7  is stored in advance as a firmware in ROM or the like. The temperature characteristic output from the temperature-based information characteristic extraction circuit  24  and the image characteristics, such as hue and saturation, output from the image characteristic extraction circuit  18  are input to the scene determination circuit  26 , where a scene is determined on the basis of these characteristics.  
      First, the scene determination circuit  26  determines whether or not the field is a portrait (Portrait) (S 1051 ). As shown in  FIG. 7 , the flags of the respective blocks are ascertained. When there is a block having a large skin-color area, a middle luminance level or more, a middle distance, and a body temperature, the photographic scene is determined to be a portrait (S 1052 ).  
      When the scene is not a portrait, a determination is then made as to whether or not the scene is a sports scene (Sports) (S 1053 ). As shown in  FIG. 7 , when there is a block having a partial movement area, a small area of the skin-color region, a low frequency of appearance of the skin-color region, an intermediate luminance level or more, and a body temperature, the scene is determined to be a sports scene (S 1054 ).  
      When the scene is not a sports scene, a determination is then made as to whether or not the scene is a beach scene (Beach) (S 1055 ). As shown in  FIG. 7 , where an upper region (an upper block) of the field has a high frequency of appearance of a blue hue area and a lower region (a lower block) has a high frequency of appearance of a low saturation area and has a high temperature, the scene is determined to be a beach (S 1056 ). The term “upper region” employed herein signifies a vertically-upward direction (the direction toward the top) in the field or an image, and the term “lower region” employed herein signifies a vertically-downward direction (the direction toward the bottom) in the field or the image.  
      When the scene is not a beach, a determination is made as to whether or not the scene is snow (Snow) (S 1057 ). As shown in  FIG. 7 , when the upper region of the field has a high frequency of appearance of the blue hue area; the lower region has a high frequency of appearance of a low saturation area; and the lower region has a low temperature, the scene is determined to be snow (S 1058 ).  
      When the scene is not snow, a determination is made as to whether or not the scene is a landscape (Landscape) (S 1059 ). As shown in  FIG. 7 , when the upper region has a great frequency of appearance of a blue hue area, and the lower region has a high frequency of appearance of a high saturation area, a long distance, and the intermediate luminance level or higher, the scene is determined to be a landscape (S 1061 ).  
      When the scene corresponds to none of these categories, the scene is determined to be a normal photographic scene which does not specify a scene (an automatic photographing mode) (S 1062 ).  
       FIG. 8  shows processing pertaining to step S 106  shown in  FIG. 2 ; namely, processing for changing photographing conditions/image parameters on a per-scene basis in accordance with the result of determination of the scene.  
      When the determined scene is a portrait, the CPU  28  sets aperture to maximum in order to make the depth of a field shallow to thus throw a background out of focus. Further, shutter speed is set in order to make the skin-color area appropriately exposed. Further, a strobe light is fired in order to prevent shading of the skin of a person. The quantity of strobe light is limited to such an extent that solid white does not appear on the person. Further, sharpness (edge processing) of a captured still image is set to a soft level.  
      When the determined scene is a sports scene, the CPU  28  sets the shutter speed as fast as possible in order to prevent movement of the object. Further, sharpness of a captured still image is set to a high level.  
      In the case where the determined scene is a beach, when the CPU  28  performs appropriate exposure control, an image having the tendency of underexposure is acquired. For this reason, the shutter speed, ISO sensitivity, and the diaphragm are set such that exposure which is greater than appropriate exposure is obtained. In relation to the image captured as a still image, white balance is set to a daylight level, and sharpness is set to a high level.  
      In the case where the determined scene is snow, when the CPU  28  performs appropriate exposure control, an image having the tendency of underexposure is acquired. For this reason, the shutter speed, the ISO sensitivity, and the diaphragm are set such that exposure which is greater than appropriate exposure is obtained. White balance is set to a normal level, and sharpness is set to a high level.  
      In the case where the determined scene is a landscape, the depth of the field is set to a high level, and exposure control for reducing the aperture as low as possible is performed with a view toward capturing subjects from a close subject to a landscape such as mountains in the distance, or the like. White balance is set to a daylight level, and sharpness is set to a high level.  
      Meanwhile, when the scene is determined to be none of the categories but a normal photographic scene, the CPU  28  controls the overall image such that appropriate exposure is achieved. Sharpness is set to a normal level.  
      As mentioned above, in the present embodiment the scene is determined in consideration of the temperature of the field, and elaborate control is performed for each determined scene, so that a high-quality image appropriate for the field can be readily obtained.  
      The temperature sensor  8  of the present embodiment detects the temperature of the field by utilization of the bifurcated light obtained from the light having entered the optical system  10 . However, the essential requirement is to be able to detect the temperature of an area falling within the angle of field, which includes the angle of view corresponding to the field obtained by the optical system  10 , independently of the optical system  10 . When having determined the photographic scene, the CPU  28  may display the result of determination on the LCD  38  to thus report the result to the user. For instance, when a scene has been determined to be a beach scene, a message of “beach scene” is displayed, or an icon signifying a beach is displayed or the like.  
     Second Embodiment  
      In the first embodiment, the image region of the field is divided into a plurality of blocks and the respective blocks are classified into the “body temperature” category, the “high temperature” category, and the “low temperature” category as the characteristic of the temperature detected by the temperature sensor  8 . However, the characteristic of the temperature may be detected in a more elaborate manner.  
       FIG. 9  shows temperature characteristics of the present embodiment. The temperature is not only classified into the “body temperature” category, the “high temperature” category, and the “low temperature” category, but also further characterized by roundness, the number of areas/regions, and positions. Roundness is classified into any of the “circle” category, the “oval” category, and the “rectangular” category. The number of areas or regions is classified into any of a “large area” category, a “small area” category, an “entirely uniform” category, an “interspersed region” category, and a “concentrated region” category. Further, position is classified into any of an “upper portion” category, a “lower portion” category, a “right portion” category, and a “left portion” category. For instance, a temperature is classified into the “body temperature,” the “large area”, the “concentrated region,” the “lower portion of an image,” and the like.  
       FIG. 10  shows a table used for determination processing performed by the scene determination circuit  26 . Roundness and the number of areas/regions as well as a mere temperature are used as temperature characteristics. When a portrait has the temperature classified into the “body temperature” category, the roundness classified into the “oval” category, the number of areas/regions classified into the “large area” category, the skin color classified into the “large area” category, the luminance classified into the “low luminance” category, and the distance classified into the “middle” category, the scene determination circuit  26  determines the scene to be a night-view portrait. Further, when a portrait has the temperature classified into the “body temperature” category, the roundness classified into the “oval” category, the number of areas/regions classified into the “large area” category, the skin color classified into the “large area” category, and the distance classified into the “short” category, the scene determination circuit  26  determines the scene to be a self-portrait. Moreover, when a portrait has the temperature classified into the “body temperature” category, the roundness classified into the “circle” or “oval” category, the number of areas/regions classified into the “large area” category, the movement classified into the “partial region” category, and the skin color classified into the “large area” category, the scene determination circuit  26  determines the scene to be a child portrait (Children). When a portrait has the temperature classified into the “body temperature” category, the roundness classified into the “circle” or “oval” category, the number of areas/regions classified into the “interspersed region” category, the skin color classified into the “high frequency of appearance” category, and the color temperature classified into the “low color temperature” category, the scene determination circuit  26  determines the scene to be a party (Party).  
      Even when a scene is anything other than a portrait but has the hue classified into a “large number of green regions” category, the saturation classified into a “large area of high saturation in the center” category, and the distance classified into the “short” category, the scene is determined to be flowers (Flower).  
      When a scene has the temperature classified into the “low temperature” category, the number of areas/regions classified into a “uniform surface” category, the saturation classified into a “large number of areas of low saturation” category, and the distance classified into the “short” category, the scene is determined to be a document (Text).  
      Further, when a scene has the luminance classified into the “low luminance” category and the distance classified into the “long” category, the scene is determined to be a night landscape (Night Landscape). When a scene has the temperature classified into the “body temperature,” the roundness classified into the “circle or oval” category, the number of areas/regions classified into the “large area” category, the skin color classified into the “large number” category, the luminance classified into a “large difference of luminance between a background and the center” category, and the distance classified into a “range of strobe light of less” category, the scene is determined to be backlight. When movement is classified into the “background” category, the action is determined to be a panning shot (Nagashidori). Further, when a scene has the temperature classified into the “high temperature” category, the number of areas/regions classified into the “interspersed region” category, the color temperature classified into the “low color temperature” category, the luminance classified into the “low luminance” category, and the distance classified into the “intermediate distance or less” category, the scene is determined to be candle light (Candle Light). When a scene has the temperature classified into the “high temperature” category, the number of areas/regions classified into the “concentrated area” category, the color temperature classified into the “low color temperature” category, and the distance classified into the “long” category, the scene is determined to be a sunset (Sunset).  
      As above, determination of a scene with higher accuracy becomes possible by means of characterizing a temperature more elaborately. Needless to say, the position of the temperature may further be adopted in  FIG. 10 . When the position of the body temperature is in a lower portion, the scene is determined to be a child or the like.  
       FIG. 11  shows processing for changing photographing conditions/image parameters for each determined scene in the present embodiment. When the scene has been determined to be a night portrait, the CPU  28  controls exposure by means of firing a strobe light. When the scene has been determined to be a self-portrait, diaphragm is set to full, and sharpness is set to a soft level. When the scene has been determined to be a child, the shutter speed is set to a high-speed shutter speed, and sharpness is set to a hard level. When the scene has been determined to be a text, exposure is controlled to such an extent that exposure, which exceeds appropriate exposure, is obtained, and sharpness is set to a hard level. The same also applies to any counterparts in the following descriptions.  
      As stated above, the accuracy of determination of a scene can be enhanced by means of increasing the sensitivity of the temperature sensor  8  and detecting the temperature characteristics with high accuracy. In the present embodiment, since the area of a body temperature can be detected with high accuracy, the area of a person can be brought into focus in conjunction with an autofocus mechanism.  
      Even in Japanese Laid-Open Patent Publication No. Hei-8-136971 of the related art, the body temperature area is detected by means of an infrared camera, and the thus-detected area is brought into focus. In the present embodiment, however, attention must be paid to the fact that a determination is rendered by means of not only a mere body temperature but also taking into consideration roundness and the number of areas/regions.  
     Third Embodiment  
      Although in the first and second embodiments the temperature of the field is detected by means of uniform sensitivity from a high temperature to a low temperature, only a specific temperature may also be selectively detected. For instance, the temperature of only the sun, only a body temperature, the temperature of only sky, the temperature of only ice or snow, or the like, is detected.  FIG. 12  shows a case where only a body temperature of an image of the field is selectively detected. Among the plurality of blocks, only the block having the body temperature is selected as an object of processing. The other blocks are not taken as an object. A scene is determined on the basis of the block that has been taken as an object of processing, and photographing conditions and parameters of image processing are adjusted.  
      Although the embodiments of the present invention have been described thus far, the present invention is not limited to the embodiments but may also be materialized in the form of other embodiments. A subject can be extracted even with low luminance of the field (or, in the worst case, even in a dark state) by utilization of temperature detection to focus control, so that a focus can be achieved without fail. Moreover, so long as a pre-flash light is fired during focusing operation, exposure can also be detected. Accordingly, more reliable photographing can also be possible even in a dark condition.  
      For instance, when the area of body temperature has been detected and the chance of a person being present in the field has been determined to be high from roundness, the number of areas/regions, and the position of the body temperature, at least two characteristic points, such as eyes, nose, mouth, and ears, are extracted from the region of the person. When the thus-extracted characteristics coincide with the characteristics of a human face, the scene may be determined to be a portrait.  
      The edge component of a temperature may be extracted while the focus is being actuated, and a peak may further be detected from the edge components, and the focus may be actuated to an optimal focus position with regard to the nearest subject. For instance, a body temperature region is detected, and a peak is detected from edge components of the body temperature region. The focus is moved to the optimal focus position with regard to the subject in the body temperature region.  
      Further, the temperature of the field is acquired while the focus is being actuated, and the image-capturing element  12  acquires an image limited to such a gain increase that the AF evaluation is not affected. Data which involve little noise and whose peak is easy to detect may be acquired on the basis of temperature data and image data.  
      Moreover, a person may be detected from the temperature of the field, and data pertaining to a pre-fired strobe light reflected from the detected person may be acquired, whereby the quantity of strobe light may also be controlled.  
     PARTS LIST  
     
         
           6  analog-to-digital circuit  
           7  analog-to-digital circuit  
           8  temperature sensor  
           9  AF sensor  
           10  optical system  
           11  half mirror  
           12  image-capturing element (S103)  
           14  AF sensor processing circuit  
           16  image-capturing element drive circuit  
           18  extraction circuit  
           22  temperature sensor control circuit  
           24  extraction circuit  
           26  determination circuit  
           28  CPU  
           30  shutter control circuit  
           32  diaphragm motor control circuit  
           34  focus motor control circuit  
           36  built in memory  
           38  color LCD  
          S 101  temperature information  
          S 102  characteristic of temperature  
          S 104  characteristic of image  
          S 105  photographic scene of the field  
          S 106  determined scene  
          S 1021  plurality of blocks  
          S 1022  body temperature  
          S 1023  body temperature  
          S 1024  high temperature  
          S 1025  high temperature  
          S 1026  low temperature  
          S 1027  classification processing  
          S 1051  portrait determination scene  
          S 1052  portrait scene  
          S 1053  sports determination scene  
          S 1054  sports scene  
          S 1055  beach determination scene  
          S 1056  beach scene  
          S 1057  snow determination scene  
          S 1058  snow scene  
          S 1059  landscape determination scene  
          S 1061  landscape scene  
          S 1062  normal photographic scene  
          T temperature  
          TL upper portion of screen  
          TH lower portion of screen  
          T 1  threshold temperature  
          T 2  threshold temperature