Abstract:
A method of improving a digital image captured by a digital camera comprising: providing a digital camera having a memory for storing known values of a color chart having a plurality of color patches of different colors and a digital image processor, using the digital camera to capture an image of the color chart to produce image values of the color patches of the color chart; operating the digital image processor to process at least some of the color patch imaged values and the stored known values of the color patches to produce a color correction matrix or profile; and storing the color correction matrix or profile to correct color images subsequently acquired by the digital camera.

Description:
FIELD OF THE INVENTION 
   This invention relates in general to producing improved digital images captured by a digital camera. 
   BACKGROUND OF THE INVENTION 
   Digital cameras, such as the Kodak DCS ProBack 645M camera, capture images of a scene using a solid state image sensor, and store the resulting image data on a removable memory device, such as a PCMCIA type III hard drive. Thumbnails of the captured images can be displayed on the camera&#39;s color LCD screen. Since scenes can have a wide range of illumination levels, these cameras include automatic exposure controls in order to adjust the camera lens f/number and exposure time to compensate for the scene illumination level. However, because of the varying reflectance levels of objects within a scene, and the limited dynamic range of image sensors, such automatic exposure control often produces unacceptable results for professional photographers. 
   As a result, such digital cameras include manual exposure overrides. The photographer can review a captured image on the camera&#39;s LCD image display to determine if the captured scene appears lighter or darker than desired, adjust the exposure settings, and can take a second picture. However, because of the small size and limited picture quality of the LCD display, it is impossible to make critical exposure judgements using the displayed image. As a result, this method is useful only for providing very coarse exposure adjustments. 
   Once the images are captured by a digital camera (such as the Kodak DCS 620 or Kodak DCS ProBack 645M cameras), they can be downloaded to a computer and processed and displayed. For example, an image processing program such as Photoshop version 6.0 by Adobe Systems Inc., San Jose, Calif. can be used to display and edit a captured image. Photoshop version 6.0 includes an “info tool” which displays the RGB code values of a particular pixel when the user lingers the cursor over a particular image area. The displayed values are the RGB code values of the processed pixels from the camera, which may include many types of non-linear quantization and processing. As a result, it is not possible to easily relate the RGB code values to the sensor exposure values of the camera when the scene was captured. Furthermore, these displayed code values are available only after the images are downloaded to the computer, and not as the images are being captured. 
   U.S. Pat. No. 5,414,537, issued May 9, 1995, inventors Omuro et al., discloses a color image processing method and apparatus in which a color image of an object is processed so that the processed image accurately portrays the colors of the object regardless of varying exposure conditions. An object and a color chart that is comprised of a plurality of color chips having known colorimetric parameters are imaged under the same predetermined exposure conditions. Then, colorimetric parameters are determined for each imaged color chip of the imaged color chart. A correlation, between the known and the determined colorimetric parameters, is computed and, on the basis of the captured correlation, the color of the imaged object is corrected. This technique is disadvantageous because it requires user input, is effected in a computer separate from the camera and only corrects for color anomalies. 
   What is needed is a digital camera that provides an easy way for the photographer to understand the sensor exposure values for different areas of a scene as the scene is captured, so that any desired exposure corrections can be made automatically and the scene can be immediately recaptured. 
   SUMMARY OF THE INVENTION 
   According to the present invention, these needs are satisfied. 
   According to a feature of the present invention, critical scene content from a captured digital image of a color target is selected and is provided information necessary for color, linearity, channel and exposure correction. 
   According to another feature of the present invention there is provided a method of improving a digital image captured by a digital camera comprising: providing a digital camera having a memory for storing known values of a color chart having a plurality of color patches of different colors and a digital image processor; using said digital camera to capture an image of said color chart to produce image values of said color patches of said color chart; operating said digital image processor to process at least some of said color patch imaged values and said stored known values of said color patches to produce a color correction matrix or profile; and storing said color correction matrix or profile to correct color images subsequently acquired by said digital camera. 
   ADVANTAGEOUS EFFECT OF THE INVENTION 
   The invention has the following advantages. 
   1. A photographer can immediately utilize correction information for all images taken in a given venue. 
   2. The correction information from color targets which are well known and used by professional photographers are utilized. 
   3. Correction information for the creation of image processing parameters that can be used continually and updated as the photographer needs are utilized. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a block diagram showing an exemplary digital camera which implements the method and incorporates the apparatus of the present invention. 
       FIG. 2  is a diagrammatic view of an exemplary color chart which can be used carrying out the present invention. 
       FIG. 3  is a flow diagram of a method for deriving linearity correction according to the invention. 
       FIGS. 4(   a ) and  4 ( b ) are graphical views illustrating linearity correction according to the invention. 
       FIG. 5  is a flow diagram of a method for determining color correction according to the invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 1  is a block diagram of an exemplary digital camera which implements the method and incorporates the apparatus of the present invention. The digital camera  30  produces digital images that are stored on the removable memory card  74 . The digital camera  30  includes a lens  32  having an aperture motor drive  34  and a shutter motor drive  35  and an electrically adjustable aperture  33  and an electrically driven mechanical shutter  36 . The lens  32  focuses light from a scene (not shown) on an image sensor  40 , for example, a single-chip color CCD image sensor, using the well known Bayer color filter pattern. The aperture  33 , shutter  36 , and image sensor  40  are controlled by respective drivers  34 ,  35  and  42 . The drivers  34 ,  35  and  42  are controlled by control signals supplied by a a control interface processor  62 . In the case of drivers  34  and  35 , these signals are supplied via a Photo Systems Interface  37 , as shown in the figure. 
   The control interface processor  62  receives inputs from the Photo Systems Interface  37 . The analog output signal from the image sensor  40  is amplified and converted to digital data by the analog signal processing (ASP)  50  and analog-to-digital (A/D) converter circuit  52 . The ASP  50  and A/D  52  include a programmable electrical gain that can be used to adjust the effective ISO speed setting of the camera. This can be done as described in commonly-assigned U.S. Pat. No. 5,610,654, issued Mar. 11, 1997, inventors Parulski et al., the disclosure of which is herein incorporated by reference. The digital data is stored in a DRAM buffer memory  64  and subsequently processed by a digital image processor  66  controlled by the firmware stored in the firmware memory  70 , which can be flash EPROM memory. Alternatively, the digital image processor  66  can be provided by custom circuitry (e.g., by one or more custom integrated circuits [ICs] designed only for use in digital cameras), or by a combination of programmable processor(s) and custom circuits. 
   The processed digital image file is provided to a memory card interface  72  which stores the digital image file on the removable memory card  74 . Removable memory cards  74  are known to those skilled in the art. For example, the removable memory card  74  can include memory cards adapted to the PCMCIA card interface standard, as described in the PC Card Standard, Release 2.0, published by the Personal Computer Memory Card International Association (PCMCIA), Sunnyvale, Calif., September 1991, or to the  CompactFlash Specification Version  1.3, published by the CompactFlash Association, Palo Alto, Calif., Aug. 5, 1998. Other types of removable memory cards, including Smart Memory cards, Secure Digital (SD) cards, and Memory Stick cards, or other types of digital memory devices, such as magnetic hard drives, magnetic tape, or optical disks, could alternatively be used to store the digital images. 
   In some embodiments, the digital image processor  66  performs color interpolation followed by color and tone correction, in order to produce rendered sRGB image data. The rendered sRGB image data is then JPEG compressed and stored as a JPEG image file on the removable memory card  74 . In other embodiments, the processor directly compressed data on the removable memory card  74 , and the image is later “finished” by processing the compressed Bayer color image data using the host PC  80 . 
   The processor  66  also creates a “thumbnail” size image that is stored in RAM memory  68  and supplied to the color LCD image display  78 , which displays the captured image for the user to review. Instead of a color LCD image display, the digital camera  30  could use an organic light emitting diode (OLED) display, or many other types of image displays. The thumbnail image can be created as described in commonly-assigned U.S. Pat. No. 5,164,831, issued Nov. 17, 1992, inventors Kuchta et al., the disclosure of which is herein incorporated by reference. The graphical user interface displayed on the color LCD image display  78  is controlled by the user interface portion of the firmware stored in the firmware memory  70 . 
   After a series of images have been taken and stored on the removable memory card  74 , the removable memory card  74  can be inserted into a card reader (not shown) in host PC  80 . Alternatively, an interface cable  77  can be used to connect between the interface  76  in the digital camera  30  and the host PC  80 . The interface cable  77  can conform to, for example, that well known IEEE 1394 interface specification, the universal serial bus (USB) interface specification, or other wired or wireless interface specifications. 
   Alternatively, the digital camera  30  could be comprised of a digital back for a 35 mm or medium format film camera. In this case, the lens  32 , aperture  34 , shutter  36  are provided as part of the film camera body, and the other components, including the image sensor  40 , image processor  66  and color LCD image display  78 , are provided as part of a separate digital camera back that is connected to the film camera body. The connection preferably includes an electrical connector (not shown), so that the lens  32 , aperture  33 , and shutter  36  can be controlled by the control interface processor  62  in the digital back. 
   According to the present invention there is provided a method and apparatus for automatically calibrating a digital camera for linearity, color, white balance and exposure. In the digital image processing path, the ultimate image quality is achieved when the processing of the images can occur with the most recent data applied in the processing path. Because of this fact, the data that occurs most recently is the data that is best for the particular capture that is being used for processing. However, there are many workflow considerations that must be overcome in order to use each individual image for processing of its data. Therefore, the next best thing is to utilize the information for processing of a set of images. This can be accomplished by capturing an image, under the conditions that are most like those of the images to be captured. The information from this one capture can be extracted and properly analyzed and then applied to the subsequent images to achieve images that have exceptional image quality under a variety of illuminants. 
   In general, according to the present invention, digital camera  30  user captures a color chart (e.g., small MacBeth 100 in  FIG. 2 ) under the illuminant or in the venue used to capture subsequent images. From the neutral patch data  102  on the chart, the camera firmware  66 ,  70  will extract information to adjust exposure, white balance and linearity. With the color patch data  106 , the camera firmware  66 ,  70  will regress the captured patch data with the reference patch data. The outcome of the regression will be either an ICC (International Color Consortium) profile or a color matrix that will colorimetrically balance the image for that set of conditions that the images are captured under. The known values for the color chart  100  are stored in firmware memory  70  and are used with the values determined from the imaged color chart  100  to effect the method of the present invention by digital image processor  66 . 
   The invention affords the user a unique opportunity and huge workflow savings in utilizing the patch data from a known chart to effect many important items in the digital processing workflow. This technique could be used for scanners as well as printers. 
   The exposure and white balance correction will be determined based upon the middle gray patch  104  of the color target  100 . Since the patch  104  is neutral, the factory determined exposure level is known and used to calculate how far over/under exposed the image may be. From this determination, the software will automatically adjust the image data to render a proper exposure. Equation 1a provides an equation for the determination of the exposure level. While equation 1b shows how the image data would be automatically corrected based upon the value from equation 1a. 
                   stops   ⁢           ⁢   from   ⁢           ⁢   MidGray     =       log   10     ⁡     (     Value     MidGray       log   10     ⁢   2         )               (     1   ⁢   a     )               where MidGray is factory determined proper exposure level for that patch  (1b)         Exposure Correction=2 Stops from MidGray      where MidGray is factory determined proper exposure level for that patch       
   The white balance correction will also be determined from the middle gray patch  104  ( FIG. 2 ). Since the patch  104  is neutral, the color of the illuminant, from a red, green, blue, perspective will be known be analyzing the red, green, blue values of the gray patch. Once these values are determined, channel gains can be calculated to be applied to the red, green and blue channels of the image, respectively. Equation 2a shows how the channel gains are calculated and equation 2b shows how the gains are applied automatically to the respective red, green and blue channels.
 
Red gain =Max channel /Red Avg  
 
Green gain =Max channel /Green Avg  
 
Blue gain =Max channel /Blue Avg   (2a)
         where Max channel =Maximum (Red, Green, Blue)
 
Red corr =RedLut[Red value ]
 
Green corr =GreenLut[Green value ]
 
Blue corr =BlueLut[Blue value ]  (2b)
   where RedLut, GreenLut, BlueLut are determined by multiplying the gains calculated from 2a by a linear curve       

   In order to enhance the image quality of the captured image, it is vital that the tonescale of the image be linear. The concept of CCDs is that they produce a linear output relative to exposure. However, to the extent that the linear paradigm is not held, color performance and therefore image quality will be hindered. 
   The other issue with linearity is that as the ISO speed of the camera is increased the linearity of the device can suffer. Therefore, having the ability to linearize the image, with actual image data, will be important for establishing an efficient workflow. 
   From the neutral scale  102  on the color chart  100 , the linearity correction will be determined. The means of determining the correction is shown in the flow diagram in  FIG. 3 . The neutral scale analysis  300  will show the level of non-linearity existent in the image for the particular capture conditions. Therefore, after a regression procedure  302 , a compensating curve is derived  304  that is the opposite of the curve that is shown via the neutral scale. The effect of the characteristic neutral scale based on the capture conditions, combined with the compensating curve will yield a linear neutral scale that will allow for much better image quality. This is illustrated in  FIGS. 4(   a ) and  4 ( b ).  FIG. 4(   a ) shows a linear curve A between image I in  and I out . In  FIG. 4(   b ), curve B shows an imaged non-linear curve B, a derived compensation curve C, and corrected linear curve A′. 
   The color correction of a digital image is the most critical part of the image processing path. It relies heavily on exposure, white balance and linearity, however, without the proper color correction, the image will be unacceptable for customer usage. The competitive advantage for Kodak lies in its ability to manipulate color. 
   The color chart  106  shown in  FIG. 2  can be used to assess the color that the camera “sees” and correct it for the color that the camera should “see”. This can be done on a venue basis. If the capture conditions are not changing, then the color correction that is done will be useful for all scenes captured under those conditions. The workflow for the user is greatly enhanced because of the fact that the user can get color balanced images in the camera, and thereby reducing the time needed in the back-end processing. The flow diagram in  FIG. 5  shows the flow that is used to determine the color correction parameters needed for proper color reproduction. First the color patch image data is analyzed ( 500 ) and then through a regression procedure ( 502 ) using the known color patch values and the imaged color patch values, a color correction matrix or profile is derived ( 504 ). The outcome of this process can be either a 3×3 matrix applied to the RGB data or it can be an ICC profile that is applied to the RGB data. 
   The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention. 
   PARTS LIST 
   
       
         30  digital camera 
         32  lens 
         33  adjustable aperture 
         34  aperture driver 
         35  shutter motor drive 
         36  mechanical shutter 
         37  Photo Systems Interface 
         40  image sensor 
         42  driver 
         50  analog Gain &amp; CDS 
         52  A/D converter circuit 
         62  control interface processor 
         64  DRAM buffer memory 
         66  digital image processor 
         68  RAM 
         70  firmware memory 
         72  memory card interface 
         74  removable memory card 
         76  interface 
         77  interface cable 
         78  LCD 
         80  PC host computer 
         100  enhanced color chart 
         102  neutral patch data 
         104  middle gray patch 
         106  color chart 
         300  neutral scale analysis 
         302  regression procedure 
         304  compensating curve derivation 
         500  color patch analysis 
         502  regression procedure 
         504  color correction matrix or profile