JP4787126B2 - Imaging apparatus, imaging method, and program - Google Patents

Description

  The present invention relates to an imaging apparatus, an imaging method, and a program. In particular, the present invention relates to an imaging device and an imaging method for capturing an image, and a program for the imaging device.

When shooting in the depth of field priority mode, if the shutter speed value obtained based on the aperture value calculated according to the depth of field is less than the predetermined value, increase the gain to set the shutter speed to the predetermined value. There has been proposed an imaging apparatus that performs shooting while setting (see, for example, Patent Document 1).
JP 2003-158667 A JP-A-6-303491

  For example, when taking a group photo of a large number of people located over a wide range from the vicinity of the imaging device to a distance, it is necessary to increase the depth of field. For this purpose, it is necessary to increase the aperture value and capture images at a low shutter speed. However, in the system described in Patent Document 1, when the shutter speed is less than a predetermined value, the shutter speed is controlled to be a predetermined value by increasing the CCD sensitivity. For this reason, when attempting to take an image with a deep depth of field, the CCD sensitivity has to be increased greatly, thereby causing a problem that the image quality is degraded.

  Accordingly, an object of the present invention is to provide an imaging apparatus, an imaging method, and a program that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.

  In order to solve the above problems, an imaging apparatus according to a first embodiment of the present invention performs photometry of an imaging unit that captures an image, a camera shake correction unit that performs camera shake correction when the imaging unit captures an image, and a subject. Based on the photometry unit, the exposure amount determination unit that determines the exposure amount that the imaging unit should be exposed when the imaging unit has a predetermined sensitivity, and the exposure amount determined by the exposure amount determination unit based on the photometry result of the photometry unit When the exposure time calculated by the exposure time calculation unit and the exposure time calculated by the exposure time calculation unit are shorter than the reference time calculated in advance, the camera shake correction unit does not perform camera shake correction, and the exposure time calculation unit calculates When the exposure time is longer than the reference time, the camera shake correction control unit that causes the camera shake correction unit to perform camera shake correction, and the exposure time calculated by the exposure time calculation unit when the exposure time calculated by the exposure time calculation unit is shorter than the reference time Time and place When the exposure time calculated by the exposure time calculation unit is longer than the reference time, the exposure time shorter than the exposure time calculated by the exposure time calculation unit and longer than the reference time, and a predetermined sensitivity. An imaging control unit that causes the imaging unit to capture an image with higher sensitivity.

  An exposure amount difference calculation unit that calculates a difference between an exposure amount obtained when the imaging unit captures an image with the same exposure time and a predetermined sensitivity as the reference time and an exposure amount determined by the exposure amount determination unit; When the exposure time calculated by the exposure time calculation unit is longer than the reference time and the exposure amount difference calculated by the exposure amount difference calculation unit is larger than a predetermined reference amount, the imaging control unit An image may be captured by the imaging unit with an exposure time shorter than the calculated exposure time and longer than the reference time, and with a sensitivity higher than a predetermined sensitivity.

  The imaging method according to the second aspect of the present invention is based on a camera shake correction stage in which camera shake correction is performed when the imaging section captures an image, a photometry stage in which photometry is performed on the subject, and a photometry result in the photometry stage. An exposure amount determining step for determining an exposure amount to be exposed by the imaging unit when the sensitivity is a predetermined sensitivity; an exposure time calculating step for calculating an exposure time from the exposure amount determined in the exposure amount determining step; and an exposure time calculating step. When the exposure time calculated in step 1 is shorter than the reference time calculated in advance, the camera shake correction step is not performed, and the camera shake correction step is performed when the exposure time calculated in the exposure time calculation step is longer than the reference time. In the camera shake correction control stage for performing camera shake correction in the exposure time calculation stage and the exposure time calculation stage when the exposure time calculated in the exposure time calculation stage is shorter than the reference time. If the exposure time calculated in step (b) and a predetermined sensitivity are used to capture an image, and the exposure time calculated in the exposure time calculation step is longer than the reference time, the reference is shorter than the exposure time calculated in the exposure time calculation step. An imaging control step of causing the imaging unit to capture an image with an exposure time longer than the time and a sensitivity higher than a predetermined sensitivity.

  According to the third aspect of the present invention, there is provided a program for an imaging apparatus that captures an image, the imaging section that captures the image, and the camera shake correction that performs camera shake correction when the imaging section captures an image. An exposure amount determination unit that determines the exposure amount to be exposed by the imaging unit when the imaging unit has a predetermined sensitivity based on the photometric result of the photometry unit, and an exposure amount determination unit An exposure time calculation unit that calculates an exposure time from the exposure amount, and an exposure time calculation unit that does not perform camera shake correction in the camera shake correction unit when the exposure time calculated by the exposure time calculation unit is shorter than a reference time calculated in advance. When the exposure time calculated is longer than the reference time, the camera shake correction control unit that causes the camera shake correction unit to perform camera shake correction, and the exposure time calculation unit calculates when the exposure time calculated by the exposure time calculation unit is shorter than the reference time. did When the exposure time calculated by the exposure time calculation unit is longer than the reference time, the exposure time is shorter than the exposure time calculated by the exposure time calculation unit, and longer than the reference time. And it is made to function as an imaging control part which makes an imaging part image a picture with sensitivity higher than predetermined sensitivity.

  The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

  According to the present invention, it is possible to prevent deterioration in image quality by increasing sensitivity more than necessary.

  Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the invention according to the scope of claims, and all combinations of features described in the embodiments are included. It is not necessarily essential for the solution of the invention.

  FIG. 1 shows an example of a block configuration of the imaging apparatus 100. The imaging apparatus 100 includes an instruction input unit 102, a focal length adjustment unit 104, a lens system 108, an imaging unit 110, an imaging control unit 120, an exposure amount difference calculation unit 122, a sensitivity setting unit 124, a camera shake correction control unit 130, and a camera shake correction unit. 132, exposure time calculation unit 140, reference time storage unit 150, combination storage unit 152, aperture value calculation unit 160, imaging mode determination unit 170, blur amount storage unit 182, blur amount detection unit 180, photometry unit 190, and exposure amount A determination unit 192 is provided.

  The imaging unit 110 captures an image. For example, the imaging unit 110 captures an image of a subject by receiving light from the subject with a CCD element. The camera shake correction unit 132 performs camera shake correction when the imaging unit 110 captures an image. Specifically, the camera shake correction unit 132 corrects camera shake by moving a correction lens including a gyro mechanism in a direction to cancel the camera shake.

  The photometry unit 190 measures the subject. Then, the exposure amount determination unit 192 determines the exposure amount that the imaging unit 110 should expose when the imaging unit 110 has a predetermined sensitivity, based on the photometric result of the photometry unit 190. For example, the exposure amount determination unit 192 determines the Ev value based on the photometry result of the photometry unit 190 and the CCD sensitivity. Then, the exposure time calculation unit 140 calculates the exposure time from the exposure amount determined by the exposure amount determination unit 192.

  When the exposure time calculated by the exposure time calculation unit 140 is shorter than the reference time calculated in advance, the camera shake correction control unit 130 does not perform the camera shake correction on the camera shake correction unit 132, and the exposure calculated by the exposure time calculation unit 140. When the time is longer than the reference time, the camera shake correction unit 132 performs camera shake correction.

  Then, when the exposure time calculated by the exposure time calculation unit 140 is shorter than the reference time, the imaging control unit 120 causes the imaging unit 110 to capture an image with the exposure time calculated by the exposure time calculation unit 140 and a predetermined sensitivity. When the exposure time calculated by the exposure time calculation unit 140 is longer than the reference time, an image is displayed on the imaging unit 110 with an exposure time shorter than the exposure time calculated by the exposure time calculation unit 140 and longer than the reference time, and with a sensitivity higher than a predetermined sensitivity. To image. As described above, the image capturing apparatus 100 captures an image without performing camera shake correction if the image can be captured at a shutter speed at which the influence of camera shake is small, and only when it is necessary to perform an image capture at a shutter speed at which the effect of camera shake becomes significant. Make corrections. Then, the imaging apparatus 100 images the subject with an exposure time longer than the reference time by applying camera shake correction. For this reason, according to the imaging device 100, a subject can be imaged without increasing sensitivity more than necessary. Therefore, according to the imaging apparatus 100, it is possible to reduce the amount of image quality degradation.

  Further, the exposure amount difference calculation unit 122 calculates the exposure amount obtained when the imaging unit 110 captures an image with the same exposure time and predetermined sensitivity as the reference time, and the exposure amount determined by the exposure amount determination unit 192. Calculate the difference. Then, the imaging control unit 120 performs exposure when the exposure time calculated by the exposure time calculation unit 140 is longer than the reference time and the exposure amount difference calculated by the exposure amount difference calculation unit 122 is larger than a predetermined reference amount. The imaging unit 110 is caused to capture an image with an exposure time shorter than the exposure time calculated by the time calculation unit 140 and longer than the reference time, and with a sensitivity higher than a predetermined sensitivity.

  Specifically, the exposure amount difference calculation unit 122 calculates the Ev value obtained when the imaging unit 110 captures an image with the same exposure time and predetermined sensitivity as the reference time, and the Ev determined by the exposure amount determination unit 192. The difference from the value is calculated. The imaging control unit 120 has the exposure time calculated by the exposure time calculation unit 140 longer than the reference time, and the difference in the Ev values calculated by the exposure amount difference calculation unit 122 is increased by the camera shake correction performed by the camera shake correction unit 132. Is larger than the expected Ev value, the imaging unit 110 is caused to capture an image with an exposure time shorter than the exposure time calculated by the exposure time calculation unit 140 and longer than the reference time, and with a sensitivity higher than a predetermined sensitivity.

  The imaging control unit 120 also determines the difference in exposure amount when the exposure time calculated by the exposure time calculation unit 140 is longer than the reference time and the exposure amount difference calculated by the exposure amount difference calculation unit 122 is larger than the reference amount. The exposure time shorter than the exposure time calculated by the exposure time calculation unit 140 by the length that can reduce the exposure amount by the difference between the exposure amount and the reference amount, and the exposure amount difference calculated by the exposure amount difference calculation unit 122 The image capturing unit 110 captures an image with a sensitivity that can increase the exposure amount by the difference from the reference amount.

  Therefore, when it is necessary to capture an image at a shutter speed at which the influence of camera shake becomes significant, the imaging apparatus 100 shortens the shutter speed and calculates a shutter speed that cannot be corrected by camera shake correction. Increase sensitivity by reducing speed. For this reason, according to the imaging device 100, it is not necessary to raise sensitivity more than necessary.

  The imaging mode determination unit 170 determines the imaging mode of the imaging unit 110. The imaging mode determination unit 170 may determine the imaging mode by the user or may determine the imaging mode based on the positional relationship of the subject. The aperture value calculation unit 160 determines the aperture value according to the imaging mode determined by the imaging mode determination unit 170. For example, the position of the subject to be focused on is determined in advance for each imaging mode, the depth of field is determined based on the distance to the subject at the determined position, and the determined depth of field is used. The aperture value may be determined. Then, the exposure time calculation unit 140 calculates the exposure time from the exposure amount determined by the exposure amount determination unit 192 and the aperture value calculated by the aperture value calculation unit 160.

  The combination storage unit 152 stores a plurality of combinations of aperture value and exposure time in advance in association with the imaging mode and the exposure amount. For example, the combination storage unit 152 stores in advance a plurality of combinations of aperture value and exposure time in association with the imaging mode and the Ev value. The combination storage unit 152 may be an aperture value and an exposure time determined by a program diagram.

  Then, the exposure time calculation unit 140 calculates the exposure time stored in the combination storage unit 152 in association with the imaging mode determined by the imaging mode determination unit 170 and the exposure amount determined by the exposure amount determination unit 192. Then, the imaging unit 110 captures an image with the aperture value stored in the combination storage unit 152 in association with the imaging mode determined by the imaging mode determination unit 170 and the exposure amount determined by the exposure amount determination unit 192. For this reason, the imaging apparatus 100 can set an appropriate aperture value and exposure time according to the imaging mode.

  The lens system 108 focuses the light from the subject and causes the imaging unit 110 to capture an image. Then, the focal length adjustment unit 104 adjusts the focal length of the lens system 108. The reference time storage unit 150 stores a reference time, which is a time indicating the upper limit of the exposure time that does not require camera shake correction. Specifically, the reference time storage unit 150 stores the reference time in association with the focal length of the lens system 108. For example, the reference time storage unit 150 stores the reference time 1 / f in association with the focal length (f) of the lens system 108.

  Then, the camera shake correction control unit 130 associates the exposure time calculated by the exposure time calculation unit 140 with the focal length of the lens system 108 adjusted by the focal length adjustment unit 104 and stores the reference time stored in the reference time storage unit 150. When the time is shorter, the camera shake correction unit 132 does not perform camera shake correction, and the exposure time calculated by the exposure time calculation unit 140 is associated with the focal length of the lens system 108 adjusted by the focal length adjustment unit 104. When 150 is longer than the stored reference time, the camera shake correction unit 132 is caused to perform camera shake correction.

  Then, the imaging control unit 120 associates the exposure time calculated by the exposure time calculation unit 140 with the reference time stored in the reference time storage unit 150 in association with the focal length of the lens system 108 adjusted by the focal length adjustment unit 104. In the case where the exposure time is short, the lens system 108 in which the imaging unit 110 captures an image with the exposure time calculated by the exposure time calculation unit 140 and a predetermined sensitivity, and the exposure time calculated by the exposure time calculation unit 140 is adjusted by the focal length adjustment unit 104. The focal length of the lens system 108 adjusted by the focal length adjustment unit 104 is shorter than the exposure time calculated by the exposure time calculation unit 140 when the reference time is longer than the reference time stored in the reference time storage unit 150 in association with the focal length of the lens system 108. The imaging unit 110 captures an image with an exposure time longer than the reference time stored in the reference time storage unit 150 and a sensitivity higher than a predetermined sensitivity. That.

  The blur amount detection unit 180 detects the blur amount of the imaging apparatus 100 when the imaging unit 110 captures an image. Further, the shake amount storage unit 182 stores the shake amount of the imaging apparatus 100 at the time of the user's imaging operation. Specifically, the shake amount storage unit 182 uses the average value of the shake amounts of the imaging device 100 detected by the shake amount detection unit 180 during imaging by the imaging unit 110 as the shake amount of the imaging device 100 during the user's imaging operation. Store. Then, the reference time storage unit 150 may store the reference time in association with the shake amount of the imaging apparatus 100.

  Then, the camera shake correction control unit 130 associates the exposure time calculated by the exposure time calculation unit 140 with the camera shake amount stored in the camera shake amount storage unit 182 and is shorter than the reference time stored in the reference time storage unit 150. In this case, when the exposure time calculated by the exposure time calculation unit 140 is longer than the reference time without the camera shake correction unit 132 performing the camera shake correction, the camera shake correction unit 132 performs the camera shake correction. Then, when the exposure time calculated by the exposure time calculation unit 140 is shorter than the reference time, the imaging control unit 120 causes the imaging unit 110 to capture an image with the exposure time calculated by the exposure time calculation unit 140 and a predetermined sensitivity. When the exposure time calculated by the exposure time calculation unit 140 is longer than the reference time, an image is displayed on the imaging unit 110 with an exposure time shorter than the exposure time calculated by the exposure time calculation unit 140 and longer than the reference time, and with a sensitivity higher than a predetermined sensitivity. To image.

  Thus, since the imaging apparatus 100 can set the reference time according to the amount of camera shake at the time of the user's operation, it can appropriately determine whether or not to perform camera shake correction according to the skill of the user. .

  The instruction input unit 102 causes the imaging unit 110 to capture an image when pressed fully by the user and causes the exposure amount determination unit 192 to perform exposure adjustment when pressed halfway by the user. Then, the shake amount detection unit 180 detects the shake amount of the imaging apparatus 100 when the instruction input unit 102 is half-pressed by the user. Then, the shake amount storage unit 182 uses the shake amount detected by the shake amount detection unit 180 as the shake amount of the imaging apparatus 100 at the time of the user's imaging operation when the instruction input unit 102 is next fully pressed by the user. Store. For this reason, since the imaging apparatus 100 can set the reference time according to the amount of blur detected when half-pressed, whether or not to perform camera shake correction according to the skill of the user currently using the imaging apparatus 100. Can be judged appropriately.

  Note that the exposure time in the present embodiment may be the shutter speed, and will be described using the shutter speed in the following description.

  FIG. 2 shows an example of a processing flow for determining imaging parameters during full auto shooting. The exposure amount determination unit 192 determines the Ev value by evaluation photometry by the photometry unit 190 (S202). Then, the exposure amount determining unit 192 refers to the program diagram (S204), determines the aperture value F based on the Ev value and the program diagram determined in S202 (S206), and determines the shutter speed S ( S208). Then, the camera shake correction control unit 130 determines whether or not S> 1 / f (S210). Note that f is a focal length of the lens system 108, and 1 / f is an example of a reference time in the present embodiment.

  If S is equal to or less than 1 / f in S210, an image is taken with the shutter speed S and the aperture value F (S224), and the process ends. In this case, the imaging apparatus 100 captures an image using the determined shutter speed S and aperture value F as they are.

  In S210, if S> 1 / f, the camera shake correction control unit 130 determines to turn on camera shake correction in the current shooting (S212). Then, the exposure amount difference calculation unit 122 calculates Ev ′, which is an Ev value obtained when the shutter speed is 1 / S (S214). Then, the exposure amount difference calculation unit 122 calculates a difference ΔEv between Ev ′ calculated in S214 and Ev calculated in S202 (S216).

  Then, the imaging control unit 120 determines whether ΔEv> 3 is satisfied (S218). Here, 3 which is a comparison target of ΔEv is an example of the reference amount in the present embodiment. When ΔEv> 3 in S218, the imaging control unit 120 sets the shutter speed shorter by ΔEv−3 than the shutter speed S calculated in S208 (S220). “Set it shorter by ΔEv−3” means that the shutter speed of the imaging unit 110 is set to the shutter speed corresponding to the Tv value increased by ΔEv−3 from the Tv value corresponding to the shutter speed S. means. In other words, this means that the shutter speed of the imaging unit 110 is set to a shutter speed corresponding to a Tv value smaller by 3 than the Tv value corresponding to the shutter speed 1 / f.

  Then, the imaging control unit 120 increases the ISO sensitivity by ΔEv−3 (S222). The camera shake correction control unit 130 causes the camera shake correction unit 132 to perform camera shake correction, and the imaging control unit 120 uses the aperture value F determined in S206, the shutter speed set in S220, and the ISO sensitivity set in S222. The subject is imaged by the imaging unit 110 (S224).

  When ΔEv is 3 or less in S218, the camera shake correction control unit 130 causes the camera shake correction unit 132 to perform camera shake correction, and the imaging control unit 120 sets the aperture values F and S208 determined in S206. The subject is imaged by the imaging unit 110 at the shutter speed and the set ISO sensitivity (S224). For this reason, the imaging device 100 performs only the camera shake correction when the shutter speed can be sufficiently covered by the camera shake correction, and performs imaging without reducing the shutter speed or increasing the ISO sensitivity. Can do.

  FIG. 3 shows an example of data stored in the combination storage unit 152. The combination storage unit 152 stores combinations of shutter speeds and aperture values in advance in association with a plurality of imaging modes and ISO sensitivities. For example, the combination storage unit 152 stores a combination of the shutter speed and the aperture value indicated by the line 300 in advance. Therefore, when the ISO sensitivity, the imaging mode, and the Ev value are determined, one combination of the aperture value and the shutter speed is determined based on the data stored in the combination storage unit 152. For example, according to the line indicated by 300, in order to obtain Ev = 14 at ISO sensitivity 100, the aperture value (F) 8 and the shutter speed 1/250 are determined.

  FIG. 4 shows an example of parameters determined at the time of camera shake correction. The first example is an example of parameters determined when NO is determined in S218. For example, when the lens system 108 captures an image with a 500 mm telephoto lens, it is assumed that the shutter speed S is determined to be 1/125 in S208 of FIG. In this case, since S> 1/500, it is determined that camera shake correction is necessary. However, ΔEv calculated in S216 is 2. This difference ΔEv = 2 is determined to be sufficiently compensated by camera shake correction that can obtain an effect of an Ev value of about 3, and imaging is performed without changing the shutter speed S and ISO sensitivity.

  The second example is an example of parameters that are determined when YES is determined in S218. For example, when the lens system 108 captures an image with a 500 mm telephoto lens, it is assumed that the shutter speed S is determined to be 1/30 in S208 of FIG. In this case, since S> 1/500, it is determined that camera shake correction is necessary. Unlike the first example, ΔEv calculated in S216 is 4. It is determined that this difference ΔEv = 4 cannot be compensated by camera shake correction that can provide an effect of an Ev value of about 3. However, the imaging control unit 120 shortens the shutter speed by an amount that cannot be compensated by camera shake correction. That is, the shutter speed S is reduced to 1/60 by one step, and the ISO sensitivity is increased by one step and set to ISO 200.

  As described above, the image capturing apparatus 100 can perform the camera shake correction only when necessary, and can capture the subject without changing the shutter speed and the ISO sensitivity depending on the case. Further, the imaging apparatus 100 can change the shutter speed and the ISO sensitivity by a necessary amount even when it is necessary to change the shutter speed and the ISO sensitivity. For this reason, it is possible to prevent the image quality from deteriorating significantly by increasing the sensitivity.

  FIG. 5 shows an example of three imaging modes. When the imaging mode determining unit 170 detects that there are a small number of persons near the imaging apparatus 100 and there is a subject other than the person at a very far distance, the imaging mode determination unit 170 performs imaging in the landscape mode with a person. decide. In addition, when the imaging mode determination unit 170 detects that there are a large number of persons near the imaging apparatus 100, the imaging mode determination unit 170 determines to perform imaging in the group photograph mode.

  Note that imaging modes such as a portrait scene mode and a group photo mode may be designated by input from the user. For example, when the pan focus mode is designated by a user instruction, the imaging parameter is determined so as to match the depth of field with the subject at positions 1 to 64.

  FIG. 6 shows an example of an imaging parameter determination flow when imaging in the landscape mode with people. The imaging apparatus 100 detects the position of the face in the image from the preliminary image captured by the imaging unit 110 (S602). At this time, the imaging apparatus 100 may detect a face based on the shape of a characteristic object such as the eyes, mouth, nose, and head and the positional relationship between the objects. Then, the imaging apparatus 100 measures the distance to each face detected in S602 (S604). Various methods such as laser ranging can be used for the distance measurement.

  Then, the imaging apparatus 100 determines the closest distance Lmin among the distances measured in S604 (S606). Then, the focal length adjustment unit 104 determines the focus position and the aperture value calculation unit 160 determines the aperture value F so as to give a depth of field between Lmin and infinity (S608). Then, the exposure time calculation unit 140 calculates the shutter speed S from the Ev value determined by the exposure amount determination unit 192 by the evaluation photometry, the aperture value F determined in S608, and the set ISO sensitivity (S610). Then, the imaging parameters are reset as necessary by the same processing as S212 to S224 in FIG.

  FIG. 7 shows an example of an imaging parameter determination flow when imaging in the group photo mode. The imaging apparatus 100 detects the position of the face in the image from the preliminary image captured by the imaging unit 110 (S702). Then, the imaging apparatus 100 measures the distance to each face detected in S702 (S704). Then, the imaging apparatus 100 determines the smallest distance Lmin and the largest distance Lmax among the distances measured in S704 (S706). Then, in order to give a depth of field between Lmin and Lmax, the focal length adjustment unit 104 determines the focus position, and the aperture value calculation unit 160 determines the aperture value F (S708). Then, the exposure time calculation unit 140 calculates the shutter speed S from the Ev value determined by the exposure amount determination unit 192 by evaluation photometry, the aperture value F determined in S708, and the set ISO sensitivity (S710). Then, the imaging parameters are reset as necessary by the same processing as S212 to S224 in FIG.

  FIG. 8 shows an example of an imaging parameter determination flow when imaging in the pan focus mode. The imaging apparatus 100 measures the distance from the preliminary image captured by the imaging unit 110 to the subject in the area of the portions 1 to 64 in the image (S802). Then, the imaging apparatus 100 determines the smallest distance Lmin and the largest distance Lmax among the distances to the respective subjects detected in S802 (S804). Then, in order to give a depth of field between Lmin and Lmax, the focal length adjustment unit 104 determines the focus position, and the aperture value calculation unit 160 determines the aperture value F (S806). Then, the exposure time calculation unit 140 calculates the shutter speed S from the Ev value determined by the exposure amount determination unit 192 by evaluation photometry, the aperture value F determined in S806, and the set ISO sensitivity (S810). Then, the imaging parameters are reset as necessary by the same processing as S212 to S224 in FIG.

  FIG. 9 shows an example of a hardware configuration of a digital camera as an example of the imaging apparatus 100. The release SW 14 supplies an imaging instruction for the S1 image (preliminary image) to the CPU. The release SW 16 supplies an image capturing instruction for the S2 image (main image) to the CPU 44. The shutter speed calculation means 20 calculates the shutter speed and supplies it to the CPU 44. The shutter speed calculation unit 20 corresponds to the exposure time calculation unit 140 of the imaging apparatus 100. The shooting condition setting unit 22 sets various shooting conditions and supplies shooting condition data to the CPU 44. The ISO sensitivity optimization unit 24 optimizes the ISO sensitivity and supplies optimized ISO sensitivity data to the CPU 44. The ISO sensitivity optimization unit 24 corresponds to the sensitivity setting unit 124 of the imaging device 100. The aperture calculator 12 calculates an aperture value and supplies the calculated aperture value data to the CPU 44. The aperture calculation unit 12 corresponds to the aperture value calculation unit 160 in the imaging apparatus 100.

  The contrast adjusting unit 28 adjusts the contrast and supplies the adjusted contrast data to the CPU 44. The Brightness adjusting unit 26 adjusts the brightness and supplies the adjusted brightness data to the CPU 44. The zoom SW 10 performs zoom setting according to a user instruction and supplies the set zoom data to the CPU 44. The zoom motor 38 drives the zoom cam 36 according to an instruction from the CPU 44 to displace the zoom optical system 34. The zoom encoder supplies zoom data of the zoom optical system 34 to the CPU 44. The iris motor driver 40 drives the iris motor. The focus encoder supplies the focus data of the zoom optical system 34 to the CPU 44. The AF motor driver drives the AF motor according to an instruction from the CPU 44. The camera shake correction unit 30 controls camera shake correction of the zoom optical system 34 based on an instruction from the CPU 44. The camera shake correction unit 30 corresponds to the camera shake correction unit 132 of the imaging apparatus 100.

  The zoom optical system 34 corresponds to the lens system 108 of the imaging device 100. The CCD 54 receives light incident through the zoom optical system 34 and generates a signal corresponding to the electric charge. The signal generated by the CCD 54 is decoded by a CDS analog decoder, the white balance is adjusted by the white balance amplifier 58, the gamma correction is performed by the γ corrector 60, the dot sequential means 62 performs the dot sequential, and the A / D converter 64. The EVR controls the white balance amplifier 58 according to an instruction from the CPU 44. The AD converter 64 converts it into a digital signal and supplies it to the memory controller 66. The memory controller 66 records the image data in the main memory as well as reads the image data from the main memory and supplies it to the bus.

  The antenna unit 52 detects a radio wave indicating position information, and supplies the detected data to the own camera position detection unit 50. The own camera position detection means 50 detects the position based on the received data and supplies the position data to the CPU 44.

  CPU 44, memory controller 66, compression / decompression 70, MPEG encoder / decoder 72, YC signal creation unit 74, external memory interface 80, wired communication means 84, wireless communication means 86, printing means 90, LCD driver 92, audio input / output means 99 Are connected to each other through a bus. The compression / decompression 70 compresses and decompresses the image signal. The MPEG encoder / decoder 72 performs MPEG encoding of image data and decoding of MPEG data. The YC signal creation unit 74 creates a YC signal from the image data. The 4: 4: 4 to 4: 2: 2 conversion unit 76 converts the 4: 4: 4 format from the YC signal creation unit 74 into the 4: 4: 2 format and supplies it to the NTSC encoder 78. The NTSC encoder 78 encodes an NTSC signal.

  The external memory interface writes data to and reads data from the external memory 82. The wired communication unit 84 performs wired communication with the external device 6. The wireless communication unit 86 performs wireless communication with the external device 6, the external printing unit 4, and the external communication infrastructure 2 through the antenna 88 and the outside with the external device 6. The printing unit 90 communicates print data with the external printing unit 4. The LCD driver 92 controls driving of the LCD 94. The audio input / output means 99 outputs an audio signal to the speaker 96 and inputs an audio signal from the microphone 98.

  FIG. 10 shows an exemplary hardware configuration of a computer 1500 related to the imaging apparatus 100. The computer 1500 includes a CPU peripheral unit including a CPU 1505, a RAM 1520, a graphic controller 1575, and a display device 1580 connected to each other by a host controller 1582, and a communication interface 1530 connected to the host controller 1582 by an input / output controller 1584. An input / output unit having a hard disk drive 1540 and a CD-ROM drive 1560, and a legacy input / output unit having a ROM 1510, a flexible disk drive 1550, and an input / output chip 1570 connected to the input / output controller 1584.

  The host controller 1582 connects the RAM 1520, the CPU 1505 that accesses the RAM 1520 at a high transfer rate, and the graphic controller 1575. The CPU 1505 operates based on programs stored in the ROM 1510 and the RAM 1520 and controls each unit. The graphic controller 1575 acquires image data generated by the CPU 1505 and the like on a frame buffer provided in the RAM 1520 and displays the image data on the display device 1580. Alternatively, the graphic controller 1575 may include a frame buffer that stores image data generated by the CPU 1505 or the like.

  The input / output controller 1584 connects the host controller 1582 to the hard disk drive 1540, the communication interface 1530, and the CD-ROM drive 1560, which are relatively high-speed input / output devices. The hard disk drive 1540 stores programs and data used by the CPU 1505 in the computer 1500. The communication interface 1530 communicates with the image capturing apparatus 100 via a network, and provides programs and data to the image capturing apparatus 100. The CD-ROM drive 1560 reads a program or data from the CD-ROM 1595 and provides it to the hard disk drive 1540 and the communication interface 1530 via the RAM 1520.

  The input / output controller 1584 is connected to the ROM 1510, the flexible disk drive 1550, and the relatively low-speed input / output device of the input / output chip 1570. The ROM 1510 stores a boot program executed when the computer 1500 is started up, a program depending on the hardware of the computer 1500, and the like. The flexible disk drive 1550 reads a program or data from the flexible disk 1590 and provides it to the hard disk drive 1540 and the communication interface 1530 via the RAM 1520. The input / output chip 1570 connects various input / output devices via a flexible disk drive 1550 and, for example, a parallel port, a serial port, a keyboard port, a mouse port, and the like.

  A program provided to the communication interface 1530 via the RAM 1520 is stored in a recording medium such as the flexible disk 1590, the CD-ROM 1595, or an IC card and provided by the user. The program is read from the recording medium, provided to the communication interface 1530 via the RAM 1520, and transmitted to the imaging apparatus 100 via the network. The program transmitted to the imaging apparatus 100 is installed and executed in the imaging apparatus 100.

  The program that is installed and executed in the imaging apparatus 100 includes the instruction input unit 102, the focal length adjustment unit 104, the lens system 108, the imaging unit 110, and the imaging control described with reference to FIGS. Unit 120, exposure difference calculation unit 122, sensitivity setting unit 124, camera shake correction control unit 130, camera shake correction unit 132, exposure time calculation unit 140, reference time storage unit 150, combination storage unit 152, aperture value calculation unit 160, imaging The mode determination unit 170, the blur amount storage unit 182, the blur amount detection unit 180, the photometry unit 190, and the exposure amount determination unit 192 are caused to function.

  The program shown above may be stored in an external storage medium. As the storage medium, in addition to the flexible disk 1590 and the CD-ROM 1595, an optical recording medium such as a DVD or PD, a magneto-optical recording medium such as an MD, a tape medium, a semiconductor memory such as an IC card, or the like can be used. Further, a storage device such as a hard disk or a RAM provided in a server system connected to a dedicated communication network or the Internet may be used as a recording medium, and the program may be provided to the computer 1500 via the network.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

1 is a diagram illustrating an example of a block configuration of an imaging apparatus 100. FIG. It is a figure which shows an example of the determination flow of the imaging parameter at the time of full auto imaging mode. It is a figure which shows an example of the data which the combination storage part 152 stores. It is a figure which shows an example of the parameter determined at the time of camera shake correction. It is a figure which shows an example of three imaging modes. It is a figure which shows an example of the determination flow of the imaging parameter in the case of imaging in person entering landscape mode. It is a figure which shows an example of the determination flow of the imaging parameter in the case of imaging in group photo mode. It is a figure which shows an example of the determination flow of the imaging parameter in the case of imaging in pan focus mode. 2 is a diagram illustrating an example of a hardware configuration of a digital camera as an example of an imaging apparatus 100. FIG. FIG. 25 is a diagram illustrating an example of a hardware configuration of a computer 1500 related to the imaging apparatus 100.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Imaging device 102 Instruction input part 104 Focal length adjustment part 108 Lens system 110 Imaging part 120 Imaging control part 122 Exposure amount difference calculation part 124 Sensitivity setting part 130 Camera shake correction control part 132 Camera shake correction part 140 Exposure time calculation part 150 Reference time storage Unit 152 combination storage unit 160 aperture value calculation unit 170 imaging mode determination unit 182 blur amount storage unit 180 blur amount detection unit 190 photometry unit 192 exposure amount determination unit

Claims (12)

An imaging device,
An imaging unit that captures an image;
An image stabilization unit that performs image stabilization when the image capturing unit captures an image;
A metering unit for metering the subject;
An exposure amount determination unit that determines an exposure amount to be exposed by the imaging unit when the imaging unit has a predetermined sensitivity based on a photometric result of the photometry unit;
An exposure time calculation unit that calculates an exposure time from the exposure amount determined by the exposure amount determination unit;
A reference time storage unit that stores a reference time in association with the amount of shake of the imaging device;
An instruction input unit that causes the exposure amount determination unit to perform exposure adjustment by being half-pressed by a user, and causes the imaging unit to capture an image by being fully pressed by a user;
A shake amount detection unit that detects a shake amount of the imaging device when the instruction input unit is half-pressed by a user;
A blur amount storage unit that stores a blur amount detected by the blur amount detection unit as a blur amount of the imaging device when the instruction input unit is fully pressed next to the half press by the user;
When the instruction input unit is fully pressed after the half-press, the exposure time calculated by the exposure time calculation unit is stored in the reference time in association with the blur amount stored in the blur amount storage unit. If the exposure time calculated by the exposure time calculation unit is longer than the reference time, the camera shake correction unit does not perform camera shake correction when the unit is shorter than the stored reference time. An image stabilization control unit for performing image stabilization,
When the instruction input unit is fully pressed after the half-press, and the exposure time calculated by the exposure time calculation unit is shorter than the reference time, the exposure time calculated by the exposure time calculation unit and the When the exposure time calculated by the exposure time calculation unit is longer than the reference time, the exposure time is shorter than the exposure time calculated by the exposure time calculation unit and longer than the reference time. An imaging apparatus comprising: an imaging control unit that causes the imaging unit to capture an image with an exposure time and a sensitivity higher than the predetermined sensitivity . Exposure amount difference calculation for calculating the difference between the exposure amount obtained when the imaging unit captures an image with the same exposure time and the predetermined sensitivity as the reference time, and the exposure amount determined by the exposure amount determination unit Further comprising
The imaging control unit, when the instruction input section is fully pressed in the following pressing the half, wherein the exposure time the exposure time calculation unit has calculated the length Itoki than the reference time, the exposure amount difference calculating unit On the condition that the difference between the calculated exposure amounts is larger than a predetermined reference amount, the exposure time is shorter than the exposure time calculated by the exposure time calculation unit and longer than the reference time, and the sensitivity is higher than the predetermined sensitivity. The imaging apparatus according to claim 1, wherein the imaging unit captures an image. The imaging control unit, when the instruction input section is fully pressed in the following pressing the half, wherein the exposure time the exposure time calculation unit has calculated the length Itoki than the reference time, the exposure amount difference calculating unit Subject to the difference of exposure amount but calculated that larger than the reference amount, the exposure time calculation section by a length which can be divided to reduce the exposure amount by the difference between the difference and the reference amount of the amount of exposure The imaging unit captures an image with an exposure time shorter than the calculated exposure time and a sensitivity that can increase the exposure amount by the difference between the exposure amount difference calculated by the exposure amount difference calculation unit and the reference amount. The imaging device according to claim 2. An imaging mode determining unit that determines an imaging mode of the imaging unit;
An aperture value calculation unit that determines an aperture value according to the imaging mode determined by the imaging mode determination unit;
The imaging apparatus according to any one of claims 1 to 3, wherein the exposure time calculation unit calculates an exposure time from the exposure amount determined by the exposure amount determination unit and the aperture value calculated by the aperture value calculation unit. An imaging mode determining unit that determines an imaging mode of the imaging unit;
A combination storage unit that stores in advance a plurality of combinations of aperture value and exposure time in association with the imaging mode and exposure amount;
The exposure time calculation unit calculates the exposure time stored in the combination storage unit in association with the imaging mode determined by the imaging mode determination unit and the exposure amount determined by the exposure amount determination unit,
The imaging unit from claim 1 for capturing an image at the aperture value the combination storing unit in association with the exposure amount of the imaging mode and the exposure amount determining unit that the imaging mode determination unit has determined is determined is stored the imaging apparatus according to any one of 3.   The depth of field is determined based on the smallest distance and the largest distance among the distances from the respective face positions of the plurality of persons detected from the preliminary image captured by the imaging unit to the imaging device. An aperture value calculation unit for calculating an aperture value based on the determined depth of field
Further comprising
  The exposure time calculation unit calculates an exposure time from the exposure amount determined by the exposure amount determination unit and the aperture value calculated by the aperture value calculation unit.
The imaging device according to any one of claims 1 to 3. A lens system that focuses light from a subject and causes the imaging unit to capture an image;
A focal length adjustment unit for adjusting a focal length of the lens system;
Further comprising
The reference time storage unit, an imaging apparatus according to any one of claims 1 to 6 for storing the reference time corresponding to the focal length of the lens system in association with the shake amount of the imaging device. A method for controlling an imaging device, comprising:
The imaging device includes a metering unit that measures a subject, an imaging unit that captures an image, a camera shake correction unit that performs camera shake correction when the imaging unit captures an image, and a reference time corresponding to the amount of camera shake. A reference time storage unit for storing
The method
When the instruction input unit that performs exposure adjustment by half-pressing and causes the imaging unit to capture an image by half-pressing is half-pressed by the user , the imaging is performed based on the photometric result of the photometric unit An exposure amount determination step of determining an exposure amount to be exposed by the imaging unit when the unit has a predetermined sensitivity;
An exposure time calculation step of calculating an exposure time from the exposure amount determined in the exposure amount determination step;
A shake amount detection step of detecting a shake amount of the imaging device when the instruction input unit is half-pressed by a user;
A blur amount storing step of storing the blur amount detected in the blur amount detecting step as a blur amount of the imaging device when the instruction input unit is fully pressed next to the half press by the user;
When the instruction input unit is fully pressed after the half-press, the exposure time calculated in the exposure time calculation step is stored in the reference time in association with the shake amount stored in the shake amount storage step. When the exposure time calculated in the exposure time calculation stage is longer than the reference time, the camera shake correction unit does not perform the camera shake correction when the time is shorter than the stored reference time. A camera shake correction control step for making the camera shake correction,
If the exposure time calculated in the exposure time calculation step is shorter than the reference time when the instruction input unit is fully pressed next to the half press, the exposure time calculated in the exposure time calculation step And when the exposure time calculated in the exposure time calculation step is longer than the reference time, the exposure time calculated in the exposure time calculation step is shorter than the exposure time calculated in the exposure time calculation step. An imaging control step of causing the imaging unit to capture an image with an exposure time longer than a reference time and a sensitivity higher than the predetermined sensitivity .   A face detection step of detecting a plurality of human faces from the preliminary image captured by the imaging unit;
  A distance measuring step of measuring a distance from each face position of the plurality of persons to the imaging device;
  A depth-of-field determination step of determining a depth of field based on the smallest distance and the largest distance among the measured distances;
  An aperture value calculating step for calculating an aperture value based on the depth of field determined in the depth of field determination step;
Further comprising
  In the exposure time calculation step, an exposure time is calculated from the exposure amount determined in the exposure amount determination step and the aperture value calculated in the aperture value calculation step.
The method of claim 8. A program for an imaging apparatus that captures an image, wherein the imaging apparatus is
An imaging unit for capturing an image;
An image stabilization unit that performs image stabilization when the imaging unit captures an image;
A metering unit for metering the subject,
An exposure amount determination unit that determines an exposure amount to be exposed by the imaging unit when the imaging unit has a predetermined sensitivity based on a photometric result of the photometry unit;
An exposure time calculation unit for calculating an exposure time from the exposure amount determined by the exposure amount determination unit;
A reference time storage unit that stores a reference time in association with the amount of blur of the imaging device;
An instruction input unit that causes the exposure amount determination unit to perform exposure adjustment by being half-pressed by a user, and that causes the imaging unit to capture an image by being fully pressed by the user;
A blur amount detection unit that detects a blur amount of the imaging device when the instruction input unit is half-pressed by a user;
A shake amount storage unit that stores a shake amount detected by the shake amount detection unit as a shake amount of the imaging apparatus when the instruction input unit is fully pressed next to the half press by the user;
When the instruction input unit is fully pressed after the half-press, the exposure time calculated by the exposure time calculation unit is stored in the reference time in association with the blur amount stored in the blur amount storage unit. If the exposure time calculated by the exposure time calculation unit is longer than the reference time, the camera shake correction unit does not perform camera shake correction when the unit is shorter than the stored reference time. An image stabilization control unit that performs image stabilization,
When the instruction input unit is fully pressed after the half-press, and the exposure time calculated by the exposure time calculation unit is shorter than the reference time, the exposure time calculated by the exposure time calculation unit and the When the exposure time calculated by the exposure time calculation unit is longer than the reference time, the exposure time is shorter than the exposure time calculated by the exposure time calculation unit and longer than the reference time. A program for causing the imaging unit to capture an image with an exposure time and a sensitivity higher than the predetermined sensitivity .   The program stores the imaging device.
  Exposure amount difference calculation for calculating the difference between the exposure amount obtained when the imaging unit captures an image with the same exposure time and the predetermined sensitivity as the reference time, and the exposure amount determined by the exposure amount determination unit Part
Further function as
  If the exposure time calculated by the exposure time calculation unit is longer than the reference time when the instruction input unit is fully pressed after the half-press, the imaging control unit is configured to display the exposure amount difference calculation unit. The exposure time is shorter than the exposure time calculated by the exposure time calculation unit and longer than the reference time, and the sensitivity is higher than the predetermined sensitivity on condition that the calculated difference in exposure amount is larger than a predetermined reference amount. Let the imaging unit capture an image
The program according to claim 10.   The program stores the imaging device.
  The depth of field is determined based on the smallest distance and the largest distance among the distances from the respective face positions of the plurality of persons detected from the preliminary image captured by the imaging unit to the imaging device. An aperture value calculation unit for calculating an aperture value based on the determined depth of field
Further function as
  The exposure time calculation unit calculates an exposure time from the exposure amount determined by the exposure amount determination unit and the aperture value calculated by the aperture value calculation unit.
The program according to claim 10 or 11.

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