JP5062072B2 - Camera system and table adjustment method - Google Patents

Description

  The present invention relates to a camera system that performs shading correction on image data obtained by imaging, and a correction table adjustment method used during the shading correction.

  One of the image processes performed on image data acquired by a digital camera or the like is a shading correction process. As is well known, the shading correction processing is a conversion characteristic between the original luminance of the target image and the video signal caused by peripheral light reduction in the imaging optical system incorporated in the digital camera, non-uniformity of sensitivity of the imaging device, and the like. This is a process for correcting the image data in which the luminance unevenness caused by the inconsistency or the like is generated so that the entire image has a uniform brightness on average.

When performing this shading correction process, a correction table having a conversion characteristic matched to the peripheral light attenuation of the camera optical system is created in advance, and the shading correction process is performed on the image data acquired using this correction table. It is common to execute. When such a correction table is used, if the optical axis of the imaging optical system described above is incorporated in the camera with a deviation from its ideal position (hereinafter, ideal position), shading correction processing is performed. In the image data, an overcorrection area, an undercorrection area, or the like occurs in the peripheral portion of the image, which causes luminance unevenness or color unevenness. For this reason, when the optical axis of the imaging optical system to be incorporated is shifted from the ideal position, the position of the correction table is shifted in accordance with the amount of positional deviation between the optical axis of the imaging optical system and the ideal position. A method has been proposed (see Patent Document 1).
JP 2006-148213 A

  However, when the optical axis of the imaging optical system is deviated from the ideal position, when the correction table is shifted by the amount of misalignment, the shading amount (light quantity difference or luminance difference) at the center of the image is very high. Since it is small, there is a drawback in that it is not possible to accurately determine the amount of positional deviation between the position of the optical axis of the imaging optical system in the image and the ideal position. Further, even if the correction table can be shifted by obtaining the positional deviation amount between the optical axis position of the imaging optical system and the ideal position in the image, the shading correction at the peripheral portion of the image is appropriately performed. There may not be.

  The present invention has been invented in order to solve the above-described problems, and an object thereof is to provide a camera system and a correction table adjustment method capable of appropriately performing shading correction on the entire image. To do.

  The camera system of the first invention divides an image acquisition unit that acquires an image by photoelectrically converting subject light, and a correction region that is larger than the size of the image acquired by the image acquisition unit into a plurality of regions, Corresponding to the image with a correction table in which a correction value at the time of shading correction is assigned to each of the plurality of divided areas and a relative position between the correction area and the image in the correction table are set in advance. A correction value assigned to a region is read from the correction table, and a shading correction unit that performs shading correction on the image, and an image corrected by the shading correction unit, a center portion of the image and a peripheral portion of the image And an evaluation value calculation unit that calculates an evaluation value for each evaluation region, and the evaluation value calculation unit. Based on the evaluation value of the serial evaluation each area, characterized by comprising a position adjustment unit for adjusting the relative position between the image and the correction region.

  In a second aspect based on the first aspect, the evaluation value calculation unit uses the evaluation value of the evaluation area at the center of the image and the evaluation value of the evaluation area at the peripheral edge of the image, Further, a shading amount of the peripheral portion of the image with respect to the central portion of the image is obtained, and the position adjustment unit is configured to determine a relative position between the image and the correction area of the correction table when the calculated shading amount is out of a preset range. It is characterized by adjusting.

  In a third aspect based on the second aspect, the relative position between the image and the correction area of the correction table is adjusted by the position adjustment unit when the shading amount calculated by the evaluation value calculation unit is calculated in advance. It is characterized by being repeatedly executed until it falls within a set range.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the evaluation value calculation unit calculates an evaluation value of the evaluation region with the four corners of the image being peripheral portions of the image. To do.

  In a fifth aspect based on the fourth aspect, the evaluation value calculation unit obtains shading amounts at the four corners of the image with respect to a central portion of the image from the evaluation value of the evaluation region, and the position adjustment unit includes: Adjusting the relative positions of the image and the correction area of the correction table when the left-right difference and the vertical difference of the shading amount at the four corners of the image with respect to the center of the image are out of a preset range. To do.

  According to a sixth aspect of the present invention, there is provided a table adjustment method in which an image acquisition step of acquiring an image by photoelectrically converting subject light and a correction region larger than the size of the image acquired by the image acquisition step are divided into a plurality of regions. In the correction table in which the correction value at the time of shading correction is assigned to each of the plurality of divided areas, the relative position between the correction area and the image is preset and assigned to the area corresponding to the image. The correction value is read from the correction table, and a shading correction step for performing shading correction on the image, and using the image corrected by the shading correction step, the central portion of the image and the peripheral portion of the image are set as evaluation regions. An evaluation value calculation step for calculating an evaluation value for each evaluation region, and the evaluation value calculated by the evaluation value calculation step Based on the evaluation value for each area, characterized by comprising a position adjustment step of adjusting the relative position between the image and the correction region.

  According to the present invention, since the relative position between the image and the correction area in the correction table is adjusted according to the evaluation value based on the shading amount at the peripheral edge of the image, the occurrence of luminance unevenness and color unevenness at the peripheral edge of the image. Can be suppressed, and appropriate shading correction can be performed on the image.

  Hereinafter, a digital camera will be described as an example of the camera system of the present invention.

  FIG. 1 is a diagram showing an electrical configuration of a digital camera 10 using the present invention. As is well known, the digital camera 10 photoelectrically converts the subject light transmitted through the imaging optical system 15 by the imaging element 16 and acquires image data from the electrical signal after the photoelectric conversion.

  The imaging optical system 15 includes a photographing lens 21 and a lens group 22 including a zoom lens and a focus lens. The zoom lens included in the lens group 22 moves along the optical axis L so as to achieve the selected imaging magnification. The focus lens slightly moves along the optical axis L when adjusting the focus of the subject image. The lens group 22 is driven and controlled by a lens driving mechanism 23.

  For example, a CCD (Charge Coupled Device), a CMOS (Complementary Metal-Oxide Semiconductor), or the like is used as the imaging element 16. The image sensor 16 receives subject light captured by the imaging optical system 15 and accumulates signal charges corresponding to the received light amount. Thereafter, the signal charge accumulated in the image sensor 16 is output to an AFE (Analog Front End) circuit 25. The driver 27 controls the accumulation of signal charges by the image sensor 16 and the output of the accumulated signal charges. Hereinafter, the signal charges accumulated by the image sensor 16 will be described as analog image signals.

  The AFE circuit 25 includes an AGC circuit and a CDS circuit (not shown). The AFE circuit 25 performs analog processing such as gain control and noise removal on the input analog image signal. The analog image signal subjected to the analog processing is output to the DFE circuit 26.

  A DFE (Digital Front End) circuit 26 converts an analog image signal subjected to analog processing by the AFE circuit 25 into a digital image signal. The converted digital image signals are collected frame by frame and recorded in the buffer memory 30 as digital image data (hereinafter referred to as image data). Image data is acquired by accumulation of signal charges in the image sensor 16, analog processing on the signal charges by the AFE circuit 25, and digital processing by the DFE circuit 26. Reference numeral 28 denotes a timing generator (TG), and the driving timing of the driver 27, the AFE circuit 25, and the DFE circuit 26 is controlled by the TG 28. Reference numeral 32 denotes a bus, and each part of the digital camera 10 is electrically connected via the bus 32.

  The image processing unit 35 performs image processing such as Bayer interpolation, shading correction, contour compensation, gamma correction, and white balance adjustment on the image data stored in the buffer memory 30. The image data that has been subjected to image processing is subjected to format processing (image post-processing) for compression using a storage method such as the JPEG method. After this formatting process, thumbnail image data and compressed image data compressed by the JPEG method at a preset compression rate are generated. The thumbnail image data and the compressed image data are collected as one image file using shooting history information described later as tag information, and are recorded in a storage medium 46 such as a memory card via the media controller 45. Reference numeral 48 denotes an LCD which displays, for example, a menu image when setting the digital camera 10 in addition to displaying a through image and an acquired image. The LCD 48 is driven and controlled by a display control unit 49.

  The image processing unit 35 has functions of a shading correction unit 51, an evaluation value calculation unit 52, and a position adjustment unit 53. The functions of the shading correction unit 51, the table adjustment unit 52, and the evaluation value calculation unit 53 are functions used at the time of manufacturing the digital camera 10, so that these functions cannot be used for a shipped digital camera. It has become.

  The shading correction unit 51 performs shading correction on image data having each color component of red (R), green (G), and blue (B) by Bayer interpolation. This shading correction is executed for each of the R, G, and B color components. The built-in memory 55 stores a correction table (hereinafter referred to as a shading correction table) used when performing shading correction for each of R, G, and B color components. In FIG. 1, the shading correction table provided for each color component is described as a single shading correction table in order to prevent the drawing from being complicated. The shading correction unit 51 uses the shading correction table 57 to perform shading correction on the image data.

As shown in FIGS. 2A and 3, the shading correction table 57 includes a plurality of areas 61 _ij (i = 1) obtained by dividing an area 60 (hereinafter, correction area) larger than the size of the image PI. , 2,... M, j = 1, 2,... N) is assigned a correction value α. The size of the correction area 60 is set, for example, when the relative position between the correction area 60 and the image PI can be adjusted by the position adjustment unit 53 described later, that is, when the imaging optical system 15 is incorporated in the camera body. It is preferable that the size satisfies a maximum value of the dimensional tolerance. The sizes of the plurality of areas 61 _ij obtained by dividing the correction area 60 may be set as appropriate.

2B is a diagram showing a change in the correction value at the cross section at the center y _c in the y direction, and FIG. 2C is a graph showing the change in the correction value α at the cross section at the center x _c in the x direction. FIG. The correction value α in the correction table is set so that the center of the correction area 60 is the minimum value and increases toward the peripheral edge of the correction area 60. That is, the correction value α is set so that the peripheral light attenuation of the imaging optical system 15 can be corrected.

Of the plurality of areas 61 _ij provided in the shading correction table 57, an area used when performing shading correction is set in advance. That is, when the correction area 60 and the image PI described above are virtually superimposed, the relative position between the correction area 60 and the image PI is set so that the center 60c of the correction area 60 and the center Ic of the image PI coincide with each other. Has been.

  It is obtained by imaging a uniform luminance surface using a shading correction table 57 in which the relative position between the correction area 60 and the image PI is set so that the center 60c of the correction area 60 and the center Ic of the image PI coincide. When the shading correction process for the image PI is performed, the following problems occur.

  In the actual digital camera 10, the position of the imaging optical system 15 to be incorporated may not be as designed, that is, the optical axis L of the imaging optical system 15 may deviate from the center Ic of the image PI. Hereinafter, the x direction in the image will be described. However, the y direction of the image is the same as the x direction, and therefore the description of the y direction is omitted here.

  As shown by the solid line in FIG. 4B, when the imaging optical system 15 is incorporated so that the optical axis L of the imaging optical system 15 coincides with the center Ic of the image PI, the acquired image PI The amount of light at the center is the maximum light amount value at the center Ic of the image PI, and the light amount value decreases parabolically toward the peripheral edge of the image PI. When shading correction is performed on such an image PI using the correction table shown in FIG. 4A, the amount of light in the corrected image PI ′ becomes substantially uniform (see the solid line in FIG. 4C). ).

  On the other hand, when the optical axis L of the imaging optical system 15 is shifted in the −x direction with respect to the center Ic of the image PI, as shown by the dotted line in FIG. 4B, the position shifted from the center Ic of the image PI. In this case, the maximum light quantity value is obtained. When shading correction is performed on such an image PI using the correction table shown in FIG. 4A, the light quantity value in the corrected image PI ′ is uniform in the center of the image PI ′. However, in the peripheral portion, there are regions where the light amount value increases due to overcorrection and regions where the light amount value decreases due to insufficient correction. When such an overcorrection or undercorrection region occurs, the obtained image PI ′ becomes an image in which unevenness in brightness or color is generated.

  In the present invention, by executing processing in the evaluation value calculation unit 52 and the position adjustment unit 53 described later, an overcorrected or undercorrected region does not occur in the shading corrected image, that is, for an acquired image. The relative position between the correction area 60 of the above-described shading correction table 57 and the acquired image PI is adjusted when the digital camera 10 is manufactured so that appropriate shading correction can be performed. The adjustment of the relative position between the correction area 60 of the shading correction table 57 and the image PI includes adjusting the relative position described above by moving the position of the correction area of the shading correction table with respect to the image, for example. .

The evaluation value calculation unit 52 obtains evaluation values for the R, G, and B color components from the image PI ′ subjected to the shading correction by the shading correction unit 51. As shown in FIG. 5, as the region of the image PI ′ for obtaining the evaluation value, for example, the central region of the image PI ′ (region indicated by H in FIG. 5) and the four corner regions of the image PI ′ (in FIG. 5). A, B, C, D). Hereinafter, these areas will be referred to as evaluation areas. These evaluation areas A, B, C, D, and H have the same size (the same number of pixels) and are, for example, the same as each area 61 _ij of the correction area 60 in the shading correction table 57 or a size that is an integral multiple. Consists of That is, as the evaluation values a, b, c, d, and h of these evaluation areas A, B, C, D, and H, for example, the pixels included in the evaluation areas A, B, C, D, and H Examples include an average value of light quantity values and a luminance value. Hereinafter, the evaluation values a, b, c, d, and h will be described by taking the average value of the light amount values of the pixels included in each of the evaluation areas A, B, C, D, and H.

  The evaluation value calculation unit 52 calculates the evaluation values a, b, c, d, and h in the evaluation areas A, B, C, D, and H described above, and then uses the following equation (1) to calculate each color component. The left-right difference and the upper-lower difference of the shading amount are calculated. Hereinafter, the left-right difference in the shading amount is p, and the up-down difference in the shading amount is q.

  The position adjustment unit 53 determines whether the left-right difference p and the vertical difference q of the shading amounts of the R, G, and B color components calculated by the evaluation value calculation unit 52 are within a predetermined range. Based on the above, the relative position between the correction area 60 in the shading correction table 57 and the acquired image is adjusted. For example, k1 is set as the threshold value for the left-right difference p in the shading amount, and k2 is set as the threshold value for the vertical difference q. These threshold values k1 and k2 are statistical values obtained in advance through experiments, calculations, and the like. The smaller the threshold values, the smaller the light / dark difference in the image PI ′ after shading correction, that is, luminance unevenness or Color unevenness can be suppressed.

  For example, when it is determined that the left-right difference p in the shading amount is −k1 <p <k1, the position adjustment unit 53 does not adjust the position between the correction region 60 of the shading correction table 57 and the image PI. On the other hand, when it is determined that the left-right difference p in the shading amount is not −k1 <p <k1, the following processing is performed. First, it is determined whether or not the value of the left-right difference p of the shading amount is a positive value (whether or not p> 0). When the value of the left-right difference p of the shading amount becomes a positive value (p> 0), the correction area 60 of the shading correction table 57 is moved in the −x direction with respect to the image PI. On the other hand, when the left-right difference p of the shading amount becomes a negative value (p <0), the correction area 60 of the shading correction table 57 is moved by one area in the x direction with respect to the image PI. .

  Similarly, when the vertical difference q of the shading amount is −k2 <q <k2, the position adjustment unit 53 does not adjust the position of the correction region 60 of the shading correction table 57 and the image PI. On the other hand, if it is determined that the shading amount difference q is not −k2 <q <k2, the following processing is performed. First, it is determined whether or not the value of the vertical difference q of the shading amount becomes a positive value (whether q> 0). When the value of the vertical difference q of the shading amount becomes a positive value (q> 0), the correction area 60 of the shading correction table 57 is moved in the −y direction with respect to the image PI. On the other hand, when the value of the vertical difference q of the shading amount becomes a negative value (q <0), the correction area 60 of the shading correction table 57 is moved by one area in the y direction with respect to the image PI. .

  The CPU 70 comprehensively controls each unit of the digital camera 10 by executing a control program (not shown). Since the CPU 70 receives operation signals from the release button 71 and the operation unit 72, the CPU 70 controls each unit of the digital camera 10 based on the input operation signals. For example, when the release button 71 is operated, an operation signal from the release button 71 is input to the CPU 70, and thus the CPU 50 performs an AE process, an AF process, and an AWB process, and then executes an imaging process. The operation unit 72 includes, for example, a cross button that is operated when various settings of the digital camera 10 are performed.

  Next, the flow of processing when adjusting the shading correction table 57 will be described with reference to the flowchart of FIG. The process shown in the flowchart of FIG. 6 is a process performed when the digital camera 10 is manufactured, and these processes are executed for each of the R, G, and B color components.

  Step S101 is processing for setting threshold values k1 and k2. The values of the threshold values k1 and k2 are set by operating the operation unit 72 by the user or operating a PC or the like connected to the digital camera 10.

  Step S102 is a process for performing imaging. In the process of step S102, imaging using a uniform luminance surface as a subject is executed. Image data is acquired by executing the processing in step S102. If the image data acquired in step S102 is image data obtained by the image sensor 16 having a filter in which, for example, R, G, and B color components are arranged in a Bayer array, the image processing unit 25 Then, Bayer interpolation processing is performed on the image data to generate image data having R, G, and B color components in each pixel.

  Step S103 is processing for performing shading correction. The processing in step S103 is executed by the shading correction unit 51.

  Step S104 is processing for calculating an evaluation value. The process of step S104 is executed by the evaluation value calculation unit 52. The evaluation value calculation unit 52 obtains evaluation values a, b, c, d, and h in the evaluation areas A, B, C, D, and H of the image PI ′ subjected to shading correction. The obtained evaluation values a, b, c, d, h in the respective evaluation areas A, B, C, D, H are recorded in the built-in memory 55.

  Step S105 is processing for initializing the left-right difference p and the up-down difference q in the shading amount. The process of step S105 is also executed by the evaluation value calculation unit 52. The process of step S105 is executed regardless of whether the left-right difference p and the vertical difference q in the shading amount are stored in the built-in memory 55 or not.

  Step S106 is processing for obtaining the left-right difference p and the up-down difference q of the shading amount. The process of step S106 is executed by the evaluation value calculation unit 52. The evaluation value calculator 52 obtains the left-right difference p and the upper-lower difference q of the shading amount by substituting the evaluation values a, b, c, d, and h into the above-described equation (1). In the expression (1), a / h, b / h, c / h, and d / h are shading amounts at the four corners of the image PI ′ with respect to the central portion of the image PI ′, and therefore the shading amount in advance. It is also possible to obtain the left-right difference p and the up-down difference q of the shading amount. The left-right difference p and the upper-lower difference q of the shading amount calculated by the process of step S106 are recorded in the built-in memory 55.

  Step S107 is a step of determining whether or not the value of the left-right difference p of the shading amount falls within the range using the threshold value k1 set in step S101. The processing in step S107 is executed by the position adjustment unit 53.

Hereinafter, the correction value α in the shading correction table 57 is assigned to each area 61 _ij of the correction region 60 so that the center of the correction region 60 is the minimum value 1 and increases in a parabolic shape toward the peripheral edge of the correction region 60. The case will be described.

  For example, when the optical axis L of the imaging optical system 15 coincides with the center Ic of the image PI, as shown by the solid line in FIG. And a parabolic shape that decreases toward the peripheral edge. When shading correction is performed on such an image PI, for example, as indicated by the solid line in FIG. 4C, the light quantity value of the image PI ′ subjected to the shading correction becomes substantially constant. In such a case, the value of the left-right difference p of the shading amount is small, and the position adjustment unit 53 determines that −k1 <p <k1 is satisfied. In such a case, since the determination in step S107 is Yes, the process proceeds to step S115.

  On the other hand, as shown by the dotted line in FIG. 4B, when the optical axis L of the imaging optical system 15 is shifted to the left or right from the center Ic of the image PI, the light amount value is the value of the image PI. The maximum value is not taken at the center xc. When shading correction is performed on such an image, as indicated by a dotted line in FIG. 4C, an area that is overcorrected or an area that is undercorrected occurs at the peripheral edge of the image PI '. When the optical axis L of the imaging optical system 15 is deviated in the x direction with respect to the center Ic of the image PI, by performing shading correction, an area that is overcorrected or an insufficient correction at the periphery of the image. Therefore, the value of the left-right difference p of the shading amount does not satisfy −k1 <p <k1. In this case, since the determination in step S107 is No, the process proceeds to step S108.

  If the determination in step S107 is No, the process proceeds to step S108. In step S107, since the left-right difference p of the shading amount does not satisfy −k1 <p <k1, whether the left-right difference p of the shading amount is a positive value, that is, p> 0 in the process of step S108. Is determined. If the left-right difference p of the shading amount satisfies p> 0, the process proceeds to step S109. On the other hand, if the left-right difference p of the shading amount does not satisfy p> 0, the process proceeds to step S110. Note that the process of step S107 is also executed by the position adjustment unit 53.

  The process of step S109 is a process of adjusting the relative position between the correction area 60 of the shading correction table 57 and the image PI to be corrected. The process of step S109 is also executed by the position adjustment unit 53. Specifically, the process in step S109 is executed when it is determined in step S108 that the left-right difference p in the shading amount satisfies p> 0. That is, in the image PI ′ subjected to the shading correction, the shading amount at the left peripheral portion of the image PI ′ is larger than the shading amount at the right peripheral portion of the image PI ′, that is, the photographing optical system 15 with respect to the center Ic of the image PI. Is shifted to the right, in the process of step S109, the correction area 60 of the shading correction table 57 is moved in the -x direction by one area, and the correction area 60, the image PI, and Adjust the relative position of. When the process of step S109 is completed, the process returns to step S103.

  Step S110 is a process of adjusting the relative position between the correction area 60 of the shading correction table 57 and the image PI to be corrected, similarly to the process of step S109. Specifically, the process of step S110 is executed when it is determined in step S108 that the left-right difference p of the shading amount does not satisfy p> 0. That is, in the shading-corrected image PI ′, the shading amount at the left peripheral portion of the image PI ′ is smaller than the shading amount at the right peripheral portion of the image PI ′, that is, the image pickup optical system 15 has the center Ic of the image PI. Since the optical axis L is shifted to the left, in the process of step S110, the correction area 60 of the shading correction table 57 is moved in the x direction by one area, and the correction area 60 and the image PI are relative to each other. Adjust the position. When the process of step S110 ends, the process returns to step S103.

  As described above, when the value of the left-right difference p of the shading amount satisfies −k1 <p <k1 in the process of step S107, the determination in step S107 is Yes, and the process proceeds to step S115.

  Step S115 is a step of determining whether or not the value of the difference q in the shading amount is within the range using the threshold value k2 set in step S101. The determination in step S115 is also executed by the position adjustment unit 53. When the optical axis L of the imaging optical system 15 substantially coincides with the center Ic of the image PI, the shading correction results in an image PI ′ having a substantially constant light amount. It is determined that k2 <q <k2. In such a case, the determination in step S115 is Yes, and thus the position adjustment of the shading correction table 57 is completed.

  On the other hand, when the optical axis L of the imaging optical system 15 is deviated upward or downward from the center of the image PI, an overcorrected region or correction is made at the upper end or lower end of the image by performing shading correction. Since an insufficient region occurs, the value of the difference q in the shading amount does not satisfy −k2 <q <k2. If it is determined that −k2 <q <k2 is not satisfied, the determination in step S115 is No, and the process proceeds to step S116.

  If the determination in step S115 is No, the process proceeds to step S116. In step S115, since the vertical difference q of the shading amount does not satisfy −k2 <q <k2, whether the vertical difference q of the shading amount is a positive value, that is, q> 0 in the process of step S116. Is determined. When the shading amount vertical difference q satisfies q> 0, the process proceeds to step S117. On the other hand, if the shading amount difference q does not satisfy q> 0, the process proceeds to step S118.

  The process of step S117 is a process of adjusting the relative position between the correction area 60 of the shading correction table 57 and the image PI. Specifically, the process of step S117 is executed when it is determined in step S116 that the shading amount difference q satisfies q> 0. That is, in the image PI ′ subjected to the shading correction, the shading amount at the upper end portion of the image PI ′ is larger than the shading amount at the lower end portion of the image PI ′, that is, the imaging optical system with respect to the center Ic of the acquired image PI. Since the 15 optical axes L are displaced upward, in the process of step S117, the correction area 60 of the shading correction table 57 is moved in the -y direction by one area, and the correction area 60 of the shading correction table 57 is moved. And the relative position of the image PI are adjusted. When the process of step S117 ends, the process returns to step S103.

  Step S118 is a process of adjusting the relative position between the correction area 60 of the shading correction table 57 and the image PI, similarly to the process of step S117. Specifically, the process in step S118 is executed when it is determined in step S116 that the shading amount difference q does not satisfy q> 0. That is, in the shading-corrected image, the shading amount at the upper end portion of the image PI ′ is smaller than the shading amount at the lower end portion of the image PI ′, that is, the optical axis L of the imaging optical system 15 with respect to the center Ic of the image PI. Is shifted downward, in the process of step S118, the correction area 60 of the shading correction table 57 is moved in the y direction by one area, and the relative position between the correction area 60 and the image PI is adjusted. . When the process of step S110 ends, the process returns to step S103.

  When the processing of step S109, step S110, step S117, and step S118 ends, the process returns to step S103, and shading correction is performed again. In this case, shading correction using the shading correction table 57 in which the relative position between the correction area 60 and the image PI is adjusted is executed. Also in this case, the processing of step S105 to step S107 is executed again, the value of the left-right difference p of the shading amount satisfies −k1 <p <k1 in the processing of step S107, and the shading amount in the processing of step S115. These processes are repeated until the value of the vertical difference q satisfies the condition −k2 <q <k2. By executing these processes, even when the imaging optical system 15 is incorporated in the digital camera 10 so that the optical axis L of the imaging optical system 15 does not coincide with the center Ic of the image PI, the shading correction table is corrected. The relative position between the 57 correction areas 60 and the image PI can be easily adjusted. By adjusting the correction table in this way, it is possible to perform appropriate seeding correction on an image acquired by the user capturing an image, and as a result, an image with suppressed color unevenness and brightness unevenness is acquired. can do.

  In this embodiment, shading correction using image data having R, G, and B color components after Bayer interpolation has been described. However, the present invention is not limited to this, and for example, image processing is performed. It is also possible to perform shading correction on the previous image data (for example, RAW image data). In this case, the luminance value of the pixel corresponding to each evaluation region or the white balance evaluation value may be used as the evaluation value.

  In this embodiment, a digital camera is taken as an example of the camera system, but the present invention is not limited to this, and a camera system including a digital camera and an image processing apparatus connected to the digital camera may be used. . In this case, the RAW image data is acquired by the digital camera, and the acquired RAW image data is output to the image processing apparatus. In the image processing apparatus, the input RAW image data may be used to adjust the relative position between the shading correction table used for shading correction and the image to be corrected. In this case, after the shading correction table is adjusted in the image processing apparatus, the adjusted shading correction table may be stored in the built-in memory of the digital camera.

  In this embodiment, the left-right difference p and the upper-lower difference q of the shading amount are calculated, and the relative position between the correction area of the shading correction table and the image is adjusted so that these values are within the threshold range. The shading correction table is not necessarily limited to this, and for example, the evaluation values a, b, c, d, and h of the evaluation areas A, B, C, D, and H are within a preset threshold range. The correction of the shading correction table is performed such that the relative position between the correction area and the image is adjusted, or the shading amounts of the evaluation areas A, B, C, and D with respect to the evaluation area X are within a preset threshold range. It is also possible to adjust the relative position between the region and the image.

  In the present embodiment, the case of adjusting the relative position between the shading correction table and the image to be corrected when performing the shading correction at the time of manufacturing the digital camera is described. However, the present invention is not limited to this. As a pre-shooting process, when a uniform luminance surface is shot by a user operation, the relative position between the correction area of the shading correction table and the image when performing shading correction may be adjusted.

  As another process for adjusting the relative position between the correction area of the shading correction table and the image at the time of performing shading correction as a process before shooting, for example, the shading correction table according to the zoom magnification at the time of shooting is used. And adjusting the relative position between the correction area and the image to be corrected. In this case, detection means for detecting the position of the zoom lens is provided inside the digital camera, and the position of the zoom lens is detected. If this detection result and the relative position between the correction area of the shading correction table and the image to be corrected are stored in association with each other, shading correction according to the position (zoom magnification) of the zoom lens at the time of shooting is performed. Can be done. In this case, the shading correction table in which the position of the zoom lens (or zoom magnification) and the relative position between the correction area and the image to be corrected are set in advance according to the position of the zoom lens (zoom magnification). A plurality of data is stored, and when shading correction is performed, a shading correction table corresponding to the position of the zoom lens may be read. In this case, in the case of a so-called single-lens reflex digital camera in which the lens barrel can be attached to and detached from the camera body, a memory that is electrically connected to the camera body at the time of mounting is built in the lens barrel. In addition, a shading correction table corresponding to the position of the zoom lens may be stored in this memory.

It is a functional block diagram which shows the structure of a digital camera. It is a figure which shows the outline | summary of a shading correction table. It is a figure which shows the outline | summary of a shading correction table. It is a figure which shows an example of the correction value in a shading correction table, the distribution state of the consideration amount value of the image acquired, and the distribution state of the consideration after shading correction. It is a figure which shows the evaluation area | region of an image. It is a flowchart which shows the flow of the process which performs table adjustment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Digital camera, 35 ... Image processing part, 51 ... Shading correction part, 52 ... Evaluation value calculation part, 53 ... Position adjustment part, 57 ... Shading correction table, 60 ... Correction area | region,

Claims (6)

An image acquisition unit that acquires an image by photoelectrically converting subject light;
A correction table in which a correction area larger than the size of the image acquired by the image acquisition unit is divided into a plurality of areas, and a correction value at the time of shading correction is assigned to each of the plurality of divided areas;
Shading for performing shading correction on the image by reading out the correction value assigned to the area corresponding to the image with the relative position between the correction area and the image in the correction table set in advance. A correction unit;
Using the image corrected by the shading correction unit, an evaluation value calculation unit that calculates an evaluation value for each evaluation region, with the central portion of the image and the peripheral portion of the image as an evaluation region;
A position adjustment unit that adjusts a relative position between the image and the correction region based on the evaluation value for each of the evaluation regions calculated by the evaluation value calculation unit;
A camera system comprising: The camera system according to claim 1,
The evaluation value calculation unit uses the evaluation value of the evaluation region at the center of the image and the evaluation value of the evaluation region at the periphery of the image to calculate the shading amount of the periphery of the image with respect to the center of the image. Seeking further,
The position adjustment unit adjusts a relative position between the image and a correction area of the correction table when the calculated shading amount is out of a preset range. The camera system according to claim 2, wherein
The adjustment of the relative position between the image and the correction area of the correction table by the position adjustment unit is repeatedly executed until the shading amount calculated by the evaluation value calculation unit falls within the preset range. A camera system characterized by that. The camera system according to any one of claims 1 to 3,
The evaluation value calculation unit calculates an evaluation value of the evaluation region in which the four corners of the image are peripheral portions of the image. The camera system according to claim 4, wherein
The evaluation value calculation unit obtains the shading amounts at the four corners of the image with respect to the central part of the image from the evaluation value of the evaluation region,
The position adjustment unit determines a relative position between the image and the correction area of the correction table when the left-right difference and the vertical difference of the shading amount of the four corners of the image with respect to the center of the image are out of a preset range. A camera system characterized by adjusting. An image acquisition step of acquiring an image by photoelectrically converting subject light;
A correction area larger than the size of the image acquired by the image acquisition step is divided into a plurality of areas, and the correction area in the correction table in which a correction value at the time of shading correction is assigned to each of the divided areas A shading correction step of reading a correction value assigned to an area corresponding to the image from the correction table and performing a shading correction on the image in a state where a relative position with the image is set in advance.
Using the image corrected by the shading correction step, an evaluation value calculating step for calculating for each evaluation region an evaluation value having the central portion of the image and the peripheral portion of the image as an evaluation region;
A position adjustment step of adjusting a relative position between the image and the correction region based on the evaluation value for each of the evaluation regions calculated by the evaluation value calculation step;
A table adjustment method characterized by comprising:

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