U.S. patent application number 11/983655 was filed with the patent office on 2008-06-19 for image processing apparatus.
This patent application is currently assigned to Seiko Epson Corporation. Invention is credited to Ikuo Hayaishi, Toshie Imai, Takahiko Koizumi.
Application Number | 20080143853 11/983655 |
Document ID | / |
Family ID | 32016226 |
Filed Date | 2008-06-19 |
United States Patent
Application |
20080143853 |
Kind Code |
A1 |
Koizumi; Takahiko ; et
al. |
June 19, 2008 |
Image processing apparatus
Abstract
When an acquired image file GF includes image processing control
information GI, a CPU executes image quality adjustment of image
data GD in an image processing mode GM specified by the image
processing control information GI. When the acquired image file GF
does not include the image processing control information GI, on
the other hand, the CPU retrieves Exif information and in the case
of successful retrieval of the Exif information, selects the image
processing mode GM based on the Exif information and executes image
quality adjustment of the image data GD in the selected image
processing mode GM. In the case where a selected shooting mode is
described in the Exif information, the selected shooting mode is
used for the selection of the image processing mode GM. In the case
where no selected shooting mode is described in the Exif
information, on the other hand, another shooting condition is used
for the selection of the image processing mode GM.
Inventors: |
Koizumi; Takahiko;
(Nagano-ken, JP) ; Hayaishi; Ikuo; (Nagano-ken,
JP) ; Imai; Toshie; (Nagano-ken, JP) |
Correspondence
Address: |
MARTINE PENILLA & GENCARELLA, LLP
710 LAKEWAY DRIVE, SUITE 200
SUNNYVALE
CA
94085
US
|
Assignee: |
Seiko Epson Corporation
|
Family ID: |
32016226 |
Appl. No.: |
11/983655 |
Filed: |
November 9, 2007 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
10634741 |
Aug 4, 2003 |
|
|
|
11983655 |
|
|
|
|
Current U.S.
Class: |
348/231.6 ;
348/E5.024 |
Current CPC
Class: |
H04N 2201/3257 20130101;
H04N 2201/0043 20130101; H04N 1/00347 20130101; H04N 2101/00
20130101; H04N 2201/0049 20130101; H04N 2201/325 20130101; H04N
1/00278 20130101; H04N 1/32128 20130101; H04N 2201/3259 20130101;
H04N 1/00188 20130101; H04N 1/00167 20130101; H04N 2201/3277
20130101; H04N 5/225 20130101; H04N 1/6086 20130101; H04N 2201/3242
20130101; H04N 2201/0041 20130101; H04N 1/00132 20130101; H04N
1/00204 20130101; H04N 1/2307 20130101; H04N 1/2158 20130101; H04N
2201/3252 20130101 |
Class at
Publication: |
348/231.6 |
International
Class: |
H04N 5/76 20060101
H04N005/76 |
Foreign Application Data
Date |
Code |
Application Number |
Aug 7, 2002 |
JP |
2002-230025(P) |
Claims
1. An image processing method that executes a series of image
processing suitable for a shooting scene selected at a time of
shooting, said image processing method comprising: acquiring image
data; retrieving image processing control information, which
specifies a scene-dependent image processing condition suitable for
the selected shooting scene and is related to the acquired image
data; in the case of successful retrieval of the image processing
control information, acquiring the scene-dependent image processing
condition specified by the retrieved image processing control
information; and executing image quality adjustment of the image
data with the acquired scene-dependent image processing
condition.
2. An image processing method in accordance with claim 1, said
image processing method further comprising: determining the
shooting scene selected at the time of shooting, based on the
shooting information, wherein said acquiring the scene-dependent
image processing condition, in the case of failed retrieval of the
image processing control information, is implemented with acquiring
the scene-dependent image processing condition suitable for the
definitely set shooting scene from said memory device.
3. An image processing apparatus that executes a series of image
processing suitable for a shooting scene selected at a time of
shooting, said image processing apparatus comprising: an image data
acquisition module that acquires image data; a memory module that
stores multiple scene-dependent image processing conditions as
combinations of values of multiple image quality-relating
parameters set in advance for multiple shooting scenes; a
scene-dependent image processing condition acquisition module that,
in the case of successful retrieval of image processing control
information, which specifies a scene-dependent image processing
condition suitable for the selected shooting scene and is related
to the acquired image data, acquires out the scene-dependent image
processing condition specified by the retrieved image processing
control information from said memory module; and an image quality
adjustment module that executes image quality adjustment of the
image data with the acquired scene-dependent image processing
condition.
4. A computer program product storing an image processing program
that causes a computer to utilize multiple scene-dependent image
processing conditions as combinations of values of multiple image
quality-relating parameters set in advance for multiple shooting
scenes and to execute a series of image processing suitable for a
shooting scene selected at a time of shooting, said image
processing program comprising: a program command that retrieves
image processing control information, which specifies a
scene-dependent image processing condition suitable for the
selected shooting scene and is related to acquired image data; a
program command that, in the case of successful retrieval of the
image processing control information, selects the scene-dependent
image processing condition specified by the retrieved image
processing control information, among the multiple scene-dependent
image processing conditions; and a program command that executes
image quality adjustment of the image data with the selected
scene-dependent image processing condition.
Description
CROSS REFERENCE TO RELATED APPLICATION
[0001] This application is a divisional of U.S. application Ser.
No. 10/634,741, filed on Aug. 4, 2003. The disclosure of this prior
application from which priority is claimed is incorporated herein
by reference.
FIELD OF TECHNOLOGY
[0002] The present invention relates to an image processing
technique that uses shooting information or information on
specification of image processing to implement the image processing
of image data.
BACKGROUND OF THE INVENTION
[0003] Digital still cameras (DSC) having shooting modes
corresponding to various shooting scenes, such as portrait and
nightscape have been widely used. In response to selection of a
shooting mode, the DSC is set to have preset values of multiple
shooting parameters, such as shutter speed and exposure,
corresponding to the selected shooting mode. The photographer is
thus not required to individually set the shooting parameters and
easily takes photographs of a subject under shooting conditions
specified by the selected shooting mode. In the case of image data
complying with a DSC file format standard Exif 2.2, the selected
shooting mode is written, together with other shooting conditions
including a shutter speed, an exposure mode, and a light source, in
a header or an equivalent portion of the image data.
[0004] The applicant of the invention has proposed a practical
technique that sets image processing control information for
specifying image processing conditions adopted in an image
processing apparatus according to the shooting mode selected in the
DSC, the shooting conditions, and the reproduction characteristics
of an output device, and outputs the settings of the image
processing control information related to image data. This
technique ensures image processing suitable for the shooting mode
selected by the photographer (that is, image processing reflecting
the intention of the photographer). The image processing control
information used in this technique is set by taking into account
the reproduction characteristics of the output device and is thus
substantially different from the shooting information, which simply
describes the shooting conditions.
[0005] The shooting information including the shooting mode is,
however, included in a greater number of image data (image files),
compared with the image processing control information. When the
image processing control information is not available, it is
desirable to utilize the shooting information and thereby make a
greater number of image data subjected to image processing suitable
for a shooting scene at the time of shooting (that is, a shooting
mode selected by the photographer).
SUMMARY OF THE INVENTION
[0006] In order to solve the above problems of the prior art
technique, the present invention aims to make a greater number of
image data subjected to a series of image processing suitable for a
shooting scene at a time of shooting each of the image data.
[0007] A first application of the invention to attain the above
object is directed to an image processing method that makes image
data, which includes shooting information obtained at a time of
shooting, subjected to a series of image processing suitable for a
selected shooting scene. The image processing method in the first
application of the invention acquires image data; retrieves
scene-dependent image processing condition specification
information, which is related to the acquired image data and is
used to specify a scene-dependent image processing condition
suitable for the selected shooting scene; specifies the selected
shooting scene based on the shooting information, in the case of
failed retrieval of the scene-dependent image processing condition
specification information; acquires a scene-dependent image
processing condition suitable for the specified shooting scene from
a memory device, which stores multiple scene-dependent image
processing conditions set for multiple shooting scenes; and
executes image quality adjustment of the image data with the
acquired scene-dependent image processing condition.
[0008] In accordance with the first application of the invention,
even when the scene-dependent image processing condition
specification information, which is used to specify the
scene-dependent image processing condition suitable for the
selected shooting scene, is not available, the image processing
method in the first application of the invention utilizes the
general shooting information given as attribute information of the
image data to obtain the scene-dependent image processing condition
suitable for the selected shooting scene and executes image quality
adjustment with the obtained scene-dependent image processing
condition. This arrangement desirably enables a greater number of
image data to be subjected to the image processing suitable for the
shooting scene at the time of shooting each of the image data.
[0009] In the first application of the invention, in the case of
successful retrieval of the scene-dependent image processing
condition specification information, the image processing method
may acquire the scene-dependent image processing condition
corresponding to the retrieved scene-dependent image processing
condition specification information from the memory device. In this
arrangement, the scene-dependent image processing condition may be
is acquired, based on the scene-dependent image processing
condition specification information representing the photographer's
intention at the time of shooting, thus ensuring execution of image
quality adjustment reflecting the intention of the
photographer.
[0010] In another preferable arrangement of the first application
of the invention, when the shooting information includes preset
information of shooting scene, the image processing method may
specify the shooting scene, based on the preset information of
shooting scene. In this arrangement, the preset information of
shooting scene at the time of shooting is utilized to acquire the
scene-dependent image processing condition, which reflects the
shooting scene, and thereby ensures execution of image quality
adjustment suitable for the shooting scene.
[0011] In the image processing method according to the first
application of the invention, one preferable procedure specifies
the shooting scene, based on information on settings of exposure
program, aperture, shutter speed, subject distance range, ISO speed
rate, and flash included in the shooting information. These pieces
of the shooting information may be used for estimation of the
shooting scene.
[0012] In the image processing method according to the first
application of the invention, when the shooting information does
not include the preset information of shooting scene, the shooting
scene may be specified, based on information on settings of
exposure program, aperture, shutter speed, subject distance range,
ISO speed rate, and flash included in the shooting information.
This arrangement ensures execution of image quality adjustment
suitable for the shooting scene, even when the information of
shooting scene is not available.
[0013] In the image processing method according to the first
application of the invention, the scene-dependent image processing
condition may be a combination of values of multiple image
quality-relating parameters, which are set in advance for each
shooting scene. This arrangement ensures adaptation of image
quality adjustment for the shooting scene with a high accuracy.
[0014] The first application of the invention is also actualized by
an image processing apparatus that makes image data, which includes
shooting information obtained at a time of shooting, subjected to a
series of image processing suitable for a selected shooting scene.
The image processing apparatus in the first application of the
invention includes: an image data acquisition module that acquires
image data; a memory module that stores multiple scene-dependent
image processing conditions set for multiple shooting scenes; a
scene-dependent image processing condition acquisition module that,
in the case of failed retrieval of scene-dependent image processing
condition specification information, which is related to the
acquired image data and is used to specify a scene-dependent image
processing condition suitable for the selected shooting scene,
specifies the selected shooting scene based on the shooting
information and acquires a scene-dependent image processing
condition suitable for the specified shooting scene from the memory
module; and an image quality adjustment module that executes image
quality adjustment of the image data with the acquired
scene-dependent image processing condition.
[0015] The image processing apparatus according to the first
application of the invention has similar functions and effects to
those of the image processing method in the first application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0016] The first application of the invention is further actualized
by a computer program product storing a program that causes a
computer to utilize multiple scene-dependent image processing
conditions set for multiple shooting scenes and to make image data,
which includes shooting information obtained at a time of shooting,
subjected to a series of image processing suitable for a selected
shooting scene. In the computer program product according to the
first application of the invention, the program includes: a
computer command that retrieves scene-dependent image processing
condition specification information, which is related to acquired
image data and is used to specify a scene-dependent image
processing condition suitable for the selected shooting scene; a
computer command that specifies the selected shooting scene based
on the shooting information, in the case of failed retrieval of the
scene-dependent image processing condition specification
information; a computer command that selects a scene-dependent
image processing condition suitable for the specified shooting
scene among the multiple scene-dependent image processing
conditions; and a computer command that executes image quality
adjustment of the image data with the selected scene-dependent
image processing condition.
[0017] The computer program product according to the first
application of the invention has similar functions and effects to
those of the image processing method in the first application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0018] A second application of the invention is directed to an
image processing method that executes a series of image processing
suitable for a shooting scene selected at a time of shooting. The
image processing method in the second application of the invention
acquires image data; retrieves image processing control
information, which specifies a scene-dependent image processing
condition suitable for the selected shooting scene and is related
to the acquired image data; in the case of successful retrieval of
the image processing control information, acquired the
scene-dependent image processing condition specified by the
retrieved image processing control information from a memory
device, which stores multiple scene-dependent image processing
conditions as combinations of values of multiple image
quality-relating parameters set in advance for multiple shooting
scenes; and executes image quality adjustment of the image data
with the acquired scene-dependent image processing condition.
[0019] The image processing method in the second application of the
invention utilizes the image processing control information, which
is used to specify the scene-dependent image processing condition
suitable for the selected shooting scene, to acquire the
scene-dependent image processing condition suitable for the
shooting scene and executes image quality adjustment with the
obtained scene-dependent image processing condition. This
arrangement desirably enables the scene-dependent image processing
condition, which represents the photographer's intention at the
time of shooting, to be obtained adequately, thus ensuring
execution of image quality adjustment reflecting the intention of
the photographer.
[0020] In one preferable arrangement of the second application of
the invention, the image processing method determines the shooting
scene selected at the time of shooting, based on the shooting
information. In the case of failed retrieval of the image
processing control information, the image processing method
acquires out the scene-dependent image processing condition
suitable for the definitely set shooting scene from the memory
device. In such cases, the procedure of this arrangement utilizes
the general shooting information given as attribute information of
the image data to acquire the scene-dependent image processing
condition suitable for the shooting scene. This desirably enables a
greater number of image data to be subjected to image quality
adjustment suitable for the shooting scene at the time of shooting
each of the image data.
[0021] The second application of the invention is also actualized
by an image processing apparatus that executes a series of image
processing suitable for a shooting scene selected at a time of
shooting. The image processing apparatus in the second application
of the invention includes: an image data acquisition module that
acquires image data; a memory module that stores multiple
scene-dependent image processing conditions as combinations of
values of multiple image quality-relating parameters set in advance
for multiple shooting scenes; a scene-dependent image processing
condition acquisition module that, in the case of successful
retrieval of image processing control information, which specifies
a scene-dependent image processing condition suitable for the
selected shooting scene and is related to the acquired image data,
acquires the scene-dependent image processing condition specified
by the retrieved image processing control information from the
memory module; and an image quality adjustment module that executes
image quality adjustment of the image data with the acquired
scene-dependent image processing condition.
[0022] The image processing apparatus according to the second
application of the invention has similar functions and effects to
those of the image processing method in the second application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0023] The second application of the invention is further
actualized by a computer program product storing an image
processing program that causes a computer to utilize multiple
scene-dependent image processing conditions as combinations of
values of multiple image quality-relating parameters set in advance
for multiple shooting scenes and to execute a series of image
processing suitable for a shooting scene selected at a time of
shooting. In the computer program product according to the second
application of the invention, the image processing program
includes: a program command that retrieves image processing control
information, which specifies a scene-dependent image processing
condition suitable for the selected shooting scene and is related
to acquired image data; a program command that, in the case of
successful retrieval of the image processing control information,
selects the scene-dependent image processing condition specified by
the retrieved image processing control information, among the
multiple scene-dependent image processing conditions; and a program
command that executes image quality adjustment of the image data
with the selected scene-dependent image processing condition.
[0024] The computer program product according to the second
application of the invention has similar functions and effects to
those of the image processing method in the second application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0025] A third application of the invention is directed to an image
processing method that makes image data, which includes shooting
information obtained at a time of shooting, subjected to a series
of image processing. The image processing method in the third
application of the invention retrieves image processing control
information, which is related to the image data and is used to
specify an image processing condition; in the case of failed
retrieval of the image processing control information, selects an
image processing condition, which is suitable for a shooting
condition at the time of shooting, based on the shooting
information from a memory device that stores multiple different
image processing conditions set for the image data; and executes
image quality adjustment of the image data with the selected image
processing condition.
[0026] In accordance with the third application of the invention,
even when the image processing control information, which is used
to specify the image processing condition, is not available, the
image processing method in the third application of the invention
utilizes the general shooting information given as attribute
information of the image data to acquire the image processing
condition, which corresponds to the image data and is suitable for
the shooting condition at the time of shooting, and executes image
quality adjustment with the obtained image processing condition.
This arrangement desirably enables a greater number of image data
to be subjected to the image processing suitable for the shooting
condition at the time of shooting each of the image data.
[0027] In one preferable arrangement of the third application of
the invention, in the case of successful retrieval of the image
processing control information, the image processing method selects
an image processing condition specified by the retrieved image
processing control information from the memory device. The
procedure of this arrangement utilizes the image processing control
information to acquire the image processing condition, thus
ensuring execution of image quality adjustment reflecting the
intention of the photographer.
[0028] In another preferable arrangement of the third application
of the invention, when the shooting information includes preset
information of shooting scene at the time of shooting, the image
processing method selects the image processing condition, based on
the preset information of shooting scene. The procedure of this
arrangement utilizes the preset information of shooting scene at
the time of shooting to acquire the image processing condition,
which reflects the shooting scene, and thereby ensures execution of
image quality adjustment suitable for the shooting scene.
[0029] In still another preferable arrangement of the third
application of the invention, the image processing method selects
the image processing condition, based on at least information on
settings of exposure program, aperture, shutter speed, subject
distance range, ISO speed rate, and flash included in the shooting
information. These pieces of the shooting information may be used
for estimation of the shooting scene.
[0030] When the shooting information does not include the preset
information of shooting scene at the time of shooting, the image
processing condition may be selected, based on at least information
on settings of exposure program, aperture, shutter speed, subject
distance range, ISO speed rate, and flash included in the shooting
information. This arrangement ensures execution of image quality
adjustment suitable for the shooting scene, even when the
information of shooting scene is not available.
[0031] In the image processing method according to the third
application of the invention, the image processing condition may be
a combination of values of multiple image quality-relating
parameters, which are set in advance for each shooting scene. This
arrangement ensures adaptation of image quality adjustment for the
shooting scene with a high accuracy.
[0032] The third application of the invention is also actualized by
an image processing apparatus that makes image data, which includes
shooting information obtained at a time of shooting, subjected to a
series of image processing. The image processing apparatus in the
third application of the invention includes: a memory module that
stores multiple different image processing conditions set for the
image data; a selection module that, in the case of failed
retrieval of image processing control information that is related
to the image data and is used to specify an image processing
condition, selects an image processing condition, which is suitable
for a shooting condition at the time of shooting, based on the
shooting information from the memory module; and an image quality
adjustment module that executes image quality adjustment of the
image data with the selected image processing condition.
[0033] The image processing apparatus according to the third
application of the invention has similar functions and effects to
those of the image processing method in the third application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0034] The third application of the invention is further actualized
by a computer program product storing an image processing program
that causes a computer to make image data, which includes shooting
information obtained at a time of shooting, subjected to a series
of image processing. In the computer program product according to
the third application of the invention, the image processing
program includes: a program command that retrieves image processing
control information that is related to the image data and is used
to specify an image processing condition; a program command that,
in the case of failed retrieval of the image processing control
information, selects an image processing condition, which is
suitable for a shooting condition at the time of shooting, based on
the shooting information among multiple different image processing
conditions set in advance for the image data; and a program command
that executes image quality adjustment of the image data with the
selected image processing condition.
[0035] The computer program product according to the third
application of the invention has similar functions and effects to
those of the image processing method in the third application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0036] A fourth application of the invention is directed to an
image processing method that executes image processing of image
data having shooting information, which is obtained at a time of
shooting and includes information on a selected shooting scene. The
image processing method in the fourth application of the invention
acquires image data; acquires a scene-dependent image processing
condition suitable for the selected shooting scene from a memory
device, which stores multiple scene-dependent image processing
conditions as image processing conditions suitable for respective
shooting scenes; and executes image quality adjustment of the image
data with the acquired scene-dependent image processing
condition.
[0037] The image processing method in the fourth application of the
invention obtains the scene-dependent image processing condition
suitable for the selected shooting scene and executes image quality
adjustment with the acquired scene-dependent image processing
condition. This arrangement enables the image data to be subjected
to image processing suitable for the shooting scene at the time of
shooting.
[0038] In one preferable arrangement of the fourth application of
the invention, the image data is associated with scene-dependent
image processing condition specification information, which is used
to specify the scene-dependent image processing condition applied
for image processing. The image processing method receives
selection information that determines which of the selected
shooting scene and the scene-dependent image processing scene
condition is to be used to acquire the scene-dependent image
processing condition, and acquires the scene-dependent image
processing condition from the memory device, according to the
received selection information.
[0039] The procedure of this arrangement acquires the
scene-dependent image processing condition, based on either the
selected shooting scene or the scene-dependent image processing
condition specification information, which is used to specify the
scene-dependent image processing condition applied for image
processing. This arrangement enables the image data to be subjected
to image processing suitable for a desired shooting scene with
desired information.
[0040] In the fourth application of the invention, the memory
device may store a first scene-dependent image processing condition
corresponding to the shooting scene and a second scene-dependent
image processing condition corresponding to the scene-dependent
image processing condition specification information. The image
processing method may select either of the first scene-dependent
image processing condition and the second scene-dependent image
processing condition according to the received selection
information, so as to acquire the scene-dependent image processing
condition. This arrangement enables the image data to be subjected
to more adequate image processing for a desired shooting scene.
[0041] The fourth application of the invention is also actualized
by an image processing apparatus that executes image processing of
image data having shooting information, which is obtained at a time
of shooting and includes information on a selected shooting scene.
The image processing apparatus in the fourth application of the
invention includes: an image data acquisition module that acquires
image data; a memory module that stores multiple scene-dependent
image processing conditions as image processing conditions suitable
for respective shooting scenes; and an image quality adjustment
module that acquires a scene-dependent image processing condition
suitable for the selected shooting scene from the memory module and
executes image quality adjustment of the image data with the
acquired scene-dependent image processing condition.
[0042] The image processing apparatus according to the fourth
application of the invention has similar functions and effects to
those of the image processing method in the fourth application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
[0043] The fourth application of the invention is further
actualized by a computer program product storing an image
processing program that causes a computer to execute image
processing of image data having shooting information, which is
obtained at a time of shooting and includes information on a
selected shooting scene. In the computer program product according
to the fourth application of the invention, the image processing
program includes: a program code that acquires image data; a
program code that acquires a scene-dependent image processing
condition suitable for the selected shooting scene from a memory
device, which stores multiple scene-dependent image processing
conditions as image processing conditions suitable for respective
shooting scenes; and a program code that executes image quality
adjustment of the image data with the acquired scene-dependent
image processing condition.
[0044] The computer program product according to the fourth
application of the invention has similar functions and effects to
those of the image processing method in the fourth application of
the invention and has various arrangements as discussed above with
regard to the image processing method.
BRIEF DESCRIPTION OF THE DRAWINGS
[0045] FIG. 1 shows an image processing system as one embodiment,
to which an image processing apparatus of the invention is
applied;
[0046] FIG. 2 is a block diagram schematically illustrating the
structure of a digital still camera that is usable for generating
image files (image data);
[0047] FIG. 3 shows selection of a shooting mode in the digital
still camera;
[0048] FIG. 4 is a block diagram schematically illustrating the
structure of a color printer functioning as an image processing
apparatus in the embodiment;
[0049] FIG. 5 shows the file structure of an Exif image file;
[0050] FIG. 6 shows the detailed internal structure of shooting
condition tags in the Exif file format used in the embodiment;
[0051] FIG. 7 shows settings of multiple image quality-relating
parameters, which are stored in an HDD 152 (or a ROM) of a personal
computer PC and define options of an image processing mode GM
specified by image processing control information GI;
[0052] FIG. 8 is a flowchart showing an image processing routine
executed by an image processing apparatus (personal computer PC) in
the embodiment;
[0053] FIG. 9 is a flowchart showing an image quality adjustment
routine with the image processing control information GI executed
by the image processing apparatus (personal computer PC) in the
embodiment;
[0054] FIG. 10 is a flowchart showing an image quality adjustment
routine with Exif information executed by the image processing
apparatus (personal computer PC) in the embodiment; and
[0055] FIG. 11 shows a table that maps the Exif information to the
image processing mode GM.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0056] The image processing apparatus of the invention is discussed
below as a preferred embodiment with reference to the accompanied
drawings.
A. Construction of Image Processing System
[0057] The construction of an image processing system including an
image processing apparatus in one embodiment is discussed below
with reference to FIGS. 1 through 4. FIG. 1 shows an image
processing system as one embodiment, to which an image processing
apparatus of the invention is applied. FIG. 2 is a block diagram
schematically illustrating the structure of a digital still camera
that is usable for generating image files (image data). FIG. 3
shows selection of a shooting mode in the digital still camera.
FIG. 4 is a block diagram schematically illustrating the structure
of a color printer functioning as an image processing apparatus in
the embodiment.
[0058] The image processing system includes a digital still camera
12 functioning as an input device to generate an image file, a
personal computer PC functioning as an image processing apparatus
to execute image processing based on the image file generated by
the digital still camera 12 and to output print image data, and a
color printer 20 functioning as an output device to output
resulting images according to the print image data. The color
printer 20 may have the image processing functions of the personal
computer PC. In this case, the color printer 20 works as a
stand-alone to implement image processing and output of resulting
images. The output device is not restricted to the printer 20 but
may be a monitor 14 like a CRT display or an LCD display or a
projector. In the description below, the color printer 20
connecting with the personal computer PC is used as the output
device.
[0059] The personal computer PC is a general-purpose computer and
includes a CPU 150 that executes an image processing program of the
invention, a RAM 151 that temporarily stores the results of
operations by the CPU 150 and image data, and a hard disk drive
(HDD) 152 that stores the image processing program. The personal
computer PC also has a card slot 153 that receives a memory card MC
inserted therein and an input output terminal 154 that connects
with a connector cable linked with the digital still camera 12.
[0060] The digital still camera 12 focuses light information on a
digital device (for example, a CCD or an electron multiplier tube)
to acquire an image, and has an optical circuit 121 including the
CCD or the like to collect the light information, an image
acquisition circuit 122 that controls the optical circuit 121 to
acquire a digital image, an image processing circuit 123 that
processes the acquired digital image, and a control circuit 124
that has a memory and controls the respective circuits, as shown in
FIG. 2. The digital still camera 12 stores the acquired images as
digital data into a memory device, such as a memory card MC. The
JPEG data format as an irreversible compression storage system and
the TIFF data format as a reversible compression storage system are
typically applied for storage of image data in the digital still
camera 12. Other storage formats like the RAW data format, the GIF
data format, and the BMP data format are also applicable for
storage of image data.
[0061] As shown in FIG. 3, the digital still camera 12 also has a
selection/set button 126 and a liquid crystal display 127, which is
used to preview each shot image and effectuate selection and
setting through operations of the selection/set button 126. The
selection/set button 126 may be used to set a shooting mode, which
specifies shooting conditions including a shutter speed, an
exposure program, and an ISO speed rate, as well as values of
multiple shooting parameters corresponding to each shooting scene,
such as twilight scene, nightscape, or portrait.
[0062] When the digital still camera 12 has the function of
specifying a series of image processing to be executed by the image
processing apparatus with image processing control information GI,
the selection/set button 126 may be used to set individual image
processing control parameters, such as lightness, contrast,
quantity of exposure correction (exposure correction value), and
white balance, or to set an image processing mode (shooting mode),
which specifies values of multiple image processing control
parameters used in the image processing apparatus according to the
shooting conditions. The selection/set button 126 may otherwise be
used to set both the shooting mode and the image processing
mode.
[0063] The digital still camera 12 maps image processing control
information GI, which is used to specify image processing of image
data executed by the image processing apparatus (the color printer
20 and the personal computer PC), or Exif information, which
represents shooting information at the time of shooting image data,
to the image data and stores the mapping in the form of an image
file GF into the memory card MC. When the user selects a shooting
mode (shooting scene), for example, portrait, nightscape, or
twilight scene, suitable for shooting conditions, the procedure
maps the selected shooting mode as the Exif information to the
image data or maps an image processing mode, which corresponds to
the selected shooting mode and specifies values or levels of
multiple image processing control parameters including contrast,
saturation, and sharpness, to the image data and stores the mapping
into the memory card MC. The multiple image processing control
parameters may include individually settable parameters like the
quantity of exposure correction and the white balance. The settings
of shooting parameters applied for each shooting mode and image
processing parameters are related to the shooting mode and are
stored on the memory in the control circuit 124 of the digital
still camera 12.
[0064] The image file GF generated by the digital still camera 12
is transmitted to the color printer 20 via a connector cable CV and
the computer PC or directly via the connector cable CV. The image
file GF is otherwise transmitted to the color printer 20 by
inserting the memory card MC, in which the image file GF has been
stored by the digital still camera 12, into a memory card slot of
the computer PC or by directly connecting the memory card MC with
the printer 20. In the structure of the embodiment, the personal
computer PC executes image processing of the image data with the
image processing control information GI and outputs the processed
image data to the color printer 20.
[0065] The color printer 20 shown in FIG. 4 is capable of
outputting color images and is, for example, an ink jet printer
that ejects four color inks, cyan (C), magenta (M), yellow (Y), and
black (K), on a printing medium to create a dot pattern and thereby
form an image. Another example of the color printer 20 is an
electrophotographic printer that transfers and fixes color toners
on a printing medium to form an image. Other color inks, light cyan
(LC), light magenta (LM), and dark yellow (DY) may also be used, in
addition to the above four color inks.
[0066] As illustrated, the color printer 20 has a mechanism that
drives print heads IH1 through IH4 mounted on a carriage 30 to
eject inks and create dots, a mechanism that activates a carriage
motor 31 to reciprocate the carriage 30 along a shaft of a platen
32, a mechanism that activates a sheet feed motor 33 to feed a cut
sheet of printing paper 40, and a control circuit 50. The mechanism
of reciprocating the carriage 30 along the shaft of the platen 32
has a sliding shaft 34 that holds the carriage 30 arranged in
parallel with the shaft of the platen 32 in a slidable manner and a
pulley 36 that supports an endless belt 35 spanned between the
carriage motor 31 and the pulley 36.
[0067] The control circuit 50 adequately controls the operations of
the sheet feed motor 33, the carriage motor 31, and the print heads
IH1 through IH4 in response to a print command sent from the
personal computer PC and outputs image data sent from the personal
computer PC as an image on a printing medium. Ink cartridge INC1
and INC2 are attached to the carriage 30. The ink cartridge INC1
keeps black (K) ink, whereas the ink cartridge INC2 keeps the other
inks, that is, the three color inks, cyan (C), magenta (M), and
yellow (Y). Additional inks of light cyan (LC), light magenta (LM),
and dark yellow (DY) may also be kept in the ink cartridge, as
mentioned previously.
B. Structure of Image File
[0068] The image file GF of this embodiment may have, for example,
a file structure in conformity with the Exif format (Exif file)
that was specified as a standard of the image file format for
digital still cameras by Japan Electronics and Information
Technology Industries Association (JEITA), a file structure in
conformity with the JFIF format (JFIF file) that was specified as a
standard for making JPEG data files compatible by three
corporations, C-Cube Microsystems, Xing Technology, and Digital
Origin (Radius), or a file structure in conformity with the TIFF
format (TIFF file) that specifies parameters relating to image data
in the form of tags. The Exif files are classified by the type of
image data stored therein into JPEG-Exif files that store JPEG
image data in an irreversible compressed form and TIFF-Exif files
that store TIFF image data in a reversible compressed form.
[0069] The general structure of an Exif image file as a JPEG data
storage file used in this embodiment is discussed below with
reference to FIGS. 5 through 7. FIG. 5 shows the file structure of
an Exif image file. FIG. 6 shows the detailed internal structure of
shooting condition tags in the Exif file format used in the
embodiment. FIG. 7 shows settings of multiple image
quality-relating parameters, which are stored in the HDD 152 (or
the ROM) of the personal computer PC and define options of an image
processing mode GM specified by the image processing control
information GI. The terminology `file structure`, `data structure`,
and `storage area` used in this embodiment represents the image of
a file or data in the storage state in a storage device.
[0070] The image file GF includes JPEG image data GD and
application marker segments APP to store attribute information of
the JPEG image data GD. The application marker segments APP (IFD)
use tags for identifying respective pieces of information, and each
piece of information may be expressed by its corresponding tag
name. The application marker segments APP shown in FIG. 5 include
tags (area) for storing the image processing control information
GI, tags (area) for storing the Exif information, and thumbnail
image data.
[0071] Settings of image quality-relating parameters applied for
image processing executed by the personal computer PC or the color
printer 20 are described in the image processing control
information GI. The image quality-relating parameters include, for
example, YCbCr to RGB color conversion matrix elements and gamma
correction values, contrast, saturation, sharpness, lightness, and
color balance of the digital still camera 12. The image processing
control information GI also includes image processing mode
specification information, which is used to specify an image
processing mode GM corresponding to a shooting mode selected at the
time of shooting. The image processing mode GM is defined by
multiple image quality-relating parameters, for example, contrast
and saturation, as shown in FIG. 7. Each of the image
quality-relating parameters takes different values corresponding to
different image processing modes GM (shooting modes). A number is
allocated to each image processing mode GM. The image processing
control information GI specifies a number to identify each image
processing mode GM.
[0072] The Exif information includes tags for storing user
information and tags for storing shooting conditions. The user
information tags include a Makernote tag arbitrarily usable by the
Exif file user (for example, the manufacturer of the DSC). The
image processing control information GI may be described in this
Makernote tag. Settings of various parameters relating to shooting
conditions including an exposure program and a shutter speed are
described in the shooting condition tags as shown in FIG. 6.
C. Image Processing Executed by Personal Computer PC
[0073] A series of image processing executed by the personal
computer PC is discussed below with reference to FIGS. 8 through
11. FIG. 8 is a flowchart showing an image processing routine
executed by the image processing apparatus (the personal computer
PC) in the embodiment. FIG. 9 is a flowchart showing an image
quality adjustment routine with the image processing control
information GI executed by the image processing apparatus (the
personal computer PC) in the embodiment. FIG. 10 is a flowchart
showing an image quality adjustment routine with the Exif
information executed by the image processing apparatus (the
personal computer PC) in the embodiment. FIG. 11 shows a table that
maps the Exif information to the image processing mode GM.
[0074] The CPU 150 of the personal computer PC activates an image
quality adjustment program, in response to insertion of the memory
card MC into the card slot 153 or in response to connection of the
connector cable CV linked with the digital still camera 12 to the
input output terminal 154. The CPU 150 first reads an image file GF
from the memory card MC according to the user's instruction and
temporarily stores the read-out image file GF into the RAM 151
(step S100).
[0075] The CPU 150 determines whether the image file GF includes
the image processing control information GI (step S110). When the
image processing control information GI is found (detected) in the
image file GF (step S110: Yes), the CPU 150 acquires the image
processing control information GI (step S120) and executes a series
of image processing (image quality adjustment) with the acquired
image processing control information GI (step S130).
[0076] The series of image processing with the image processing
control information GI is described with reference to FIG. 9. The
CPU 150 extends the image data GD included in the read-out image
file GF and sequentially carries out matrix algebra with a matrix S
on the extended image data GD, gamma correction with gamma
correction values specified by the acquired image processing
control information GI, and matrix algebra with a matrix N.sup.-1M
including a matrix M, so as to implement color conversion of YCbCr
into wRGB (step S200).
[0077] The image file GF processed according to this flowchart
stores JPEG image data, which represent YCbCr data in a compressed
form. RGB data are generally used for image processing executed by
the personal computer PC and the printer. Extension (decoding) of
the JPEG data and the color conversion of YCbCr data into RGB data
are accordingly required. The matrix S is typically used for
conversion of YCbCr data into RGB data in the JFIF format as is
known in the art, and is thus not specifically described here. For
linearization of the relation to XYZ values in the course of color
conversion, the gamma correction is carried out with the gamma
correction values specified by the image processing control
information GI to attain linearization of the image data GD.
[0078] The procedure of this embodiment carries out RGB to wRGB
color conversion with the matrix N.sup.-1M including the matrix M,
which takes into account the color reproduction characteristics of
the color printer 20, in addition to the general YCbCr to RGB color
conversion with the matrix S. The matrix M has elements specified
by the image processing control information GI, and is used to
convert the color space from an RGB color space (target color
space) that defines (specifies) RGB data after the matrix algebra
with the matrix S into an XYZ color space that is a
device-dependent color space. When the RGB data after the matrix
algebra with the matrix S have RGB values out of the color range of
an sRGB color space, a wRGB color space at least partly having a
wider color range than the sRGB color space is specified as the
color space defining the RGB data after matrix algebra with the
matrix S. This arrangement effectively prevents loss of the RGB
values and leads to a subsequent wider wRGB color space (working
color space). The matrix N is used to convert the color space from
an RGB color space allowed by the color printer 20, for example, a
wRGB color space, into an XYZ color space. The matrix N.sup.-1M is
a composite matrix to attain color conversion from RGB to XYZ to
wRGB.
[0079] The CPU 150 acquires the image processing mode GM specified
by the image processing control information GI (step S210) and
executes image quality adjustment of the resulting RGB data
obtained by the color conversion with a set of parameters specified
by the acquired image processing mode GM (step S220). According to
a concrete procedure, the CPU 150 carries out image quality
adjustment with the settings of the image quality-relating
parameters defined by one of the options 1 through 11 of the image
processing modes GM shown in FIG. 7, which corresponds to the
number specified by the image processing control information GI.
The procedure of image quality adjustment is explained in detail.
The CPU 150 analyzes the image data GD in units of pixel and
obtains values of various characteristic parameters representing
the characteristics of the image data GD, for example, image
statistics like a minimum luminance, a maximum luminance, and a
representative lightness. The CPU 150 specifies correction values
to cancel or at least reduce differences between reference values,
which are preset for the respective characteristic parameters and
are stored in the HDD 152, and the image statistics obtained by the
analysis, and corrects the RGB values of the image data GD. The
correction of the image data GD, for example, corrects a tone
curve, which defines a relation between input and output, with the
specified correction values and substitutes the image data GD as an
input into the corrected tone curve.
[0080] The parameter values specified by the image processing mode
GM are used to change the degree of cancellation or the degree of
reduction (the amount of correction) of the difference between the
reference value and the image statistic, while being directly
reflected on the amount of correction (the correction value).
[0081] For example, when a number `2` is set as the image
processing mode GM, the degrees of correction to the reference
values are set as slightly softer (slightly weaker) for contrast,
slightly brighter (slightly stronger) for lightness, standard for
color balance, slightly lower (slightly weaker) for saturation, and
slightly weaker for sharpness. The flesh color is set as the stored
color, so that flesh color data (RGB values) stored in advance in
the HDD 152 are used for the image processing. The noise reduction
is set OFF. The image quality adjustment is carried out in the
image processing mode corresponding to each shooting scene. When
the selected shooting scene is twilight scene, for example, red
color seepage is not removed. When the selected shooting scene is
nightscape, in another example, the image data is not corrected to
be brighter by lightness correction. Namely this arrangement
ensures execution of image quality adjustment reflecting the
intention of the photographer.
[0082] The image processing control information GI may include
individually settable, image quality-relating parameters, such as
lightness and contrast, other than a set of image quality-relating
parameters for specifying the image processing mode GM. Such
individually settable parameters are not specifically described
here.
[0083] The CPU 150 carries out color conversion to convert the
resulting image data (RGB data) after the image quality adjustment
into CMYK data (step S230), and returns to the image processing
routine shown in FIG. 8. This process converts the color system of
the image data to the CMYK color system adopted by the color
printer 20 for execution of printing. A concrete procedure refers
to a lookup table, which maps the RGB color system to the CMYK
color system and is stored in the HDD 152 (ROM).
[0084] When the series of image processing discussed above is
concluded and the program returns to the image processing routine
shown in FIG. 8, the CPU 150 carries out a print output process of
the resulting image data (step S140) and then exits from this
processing routine. In the print output process, the CPU 150
successively executes a halftoning process and a resolution
conversion process and transmits the processed data as raster data
to the control circuit 50 of the color printer 20.
[0085] When the image processing control information GI is not
detected in the image file GF (step S110: No), the CPU 150
determines whether the Exif information is detected in the image
file GF (step S150). When the Exif information is not retrieved in
the image file GF (step S150: No), the CPU 150 carries out a series
of standard image processing with preset image processing
conditions, which do not depend upon the selected shooting mode
(step S180), outputs the processed image data (step S140), and
exits from this processing routine. The standard image processing
may execute image quality adjustment with reference values.
[0086] When the Exif information is retrieved in the image file GF
(step S150: Yes), on the other hand, the CPU 150 acquires the Exif
information (step S160) and carries out a series of image
processing (image quality adjustment) with the acquired Exif
information (step S170).
[0087] The series of image processing with the Exif information is
discussed below with reference to FIG. 10. The CPU 150 extends the
image data GD included in the read-out image file GF and carries
out matrix algebra with the matrix S on the extended image data GD,
so as to attain YCbCr to RGB color conversion (step S300). The CPU
150 subsequently determines whether a selected shooting mode, for
example, portrait, twilight scene, or nightscape, is described in
the Exif information (step S310).
[0088] When the shooting mode is detected in the Exif information
(step S310: Yes), the CPU 150 selects and acquires the image
processing mode GM corresponding to the shooting mode described in
the Exif information (step S320) and executes image quality
adjustment in the acquired image processing mode GM (step S330). In
general, the number of shooting modes described as the Exif
information is less than the number of image processing modes GM.
No problem accordingly arises in the mapping of the Exif
information to the image processing mode GM. When the number of
shooting modes described as the Exif information exceeds the number
of image processing modes GM, the number of image processing modes
GM is simply to be increased. The image quality adjustment in the
image processing mode GM follows the procedure of image processing
with the image processing control information GI discussed
above.
[0089] When the shooting mode is not detected in the Exif
information (step S310: No), on the other hand, the CPU 150 selects
and acquires the image processing mode GM based on other shooting
conditions described in the Exif information (step S340) and
executes image quality adjustment in the acquired image processing
mode GM (step S330). A table shown in FIG. 11 is, for example,
applicable for the mapping of the shooting conditions to the image
processing mode GM. The shooting conditions used in this embodiment
are a combination of an exposure program for setting the priority
to either of the shooting parameters, the exposure or the shutter
speed, an aperture value (F number) representing the setting of
light exposure to the CCD, a shutter speed representing the setting
of an exposure time to the CCD, a subject distance range, an ISO
speed rate representing the sensitizing quantity, and a flash
operating state like prohibited emission or forcible emission.
These shooting conditions are only illustrative and not restrictive
in any sense. Other shooting conditions including white balance,
gain control, contrast, saturation, and sharpness of shooting, a
digital zoom magnification, an exposure time, a light source, and a
subject area may adequately be added to the above combination or
used in different combinations.
[0090] The CPU 150 carries out color conversion to convert the
resulting image data (RGB data) after the image quality adjustment
into CMYK data (step S350), and returns to the image processing
routine shown in FIG. 8. This process converts the color system of
the image data to the CMYK color system adopted by the color
printer 20 for execution of printing. A concrete procedure refers
to a lookup table, which maps the RGB color system to the CMYK
color system and is stored in the HDD 152 (ROM).
[0091] When the series of image processing discussed above is
concluded and the program returns to the image processing routine
shown in FIG. 8, the CPU 150 carries out the print output process
of the resulting image data (step S140) and then exits from this
processing routine. In the print output process, the CPU 150
successively executes a halftoning process and a resolution
conversion process and transmits the processed data as raster data
to the control circuit 50 of the color printer 20.
[0092] As described above, when the image processing control
information GI includes the information for specifying the image
processing mode GM, the personal computer PC functioning as the
image processing apparatus of the embodiment executes image
processing (image quality adjustment) in the image processing mode
GM selected according to the mode-specifying information. This
arrangement ensures execution of image quality adjustment
corresponding to the shooting mode selected at the time of
shooting, that is, image processing to give the photographer's
desired output image.
[0093] When the information for specifying the image processing
mode GM is not included in the image processing control information
GI, the procedure executes image quality adjustment in the selected
image processing mode GM corresponding to the shooting mode
described as the Exif information. This arrangement ensures
execution of image quality adjustment corresponding to the shooting
mode selected at the time of shooting, that is, image processing
that reflects the intention of the photographer.
[0094] When the shooting mode is not described as the Exif
information, the procedure uses the Exif information other than the
shooting mode to select the image processing mode GM corresponding
to the shooting mode at the time of shooting and executes image
quality adjustment in the selected image processing mode GM. As
long as the Exif information is included in the image file GF, this
arrangement ensures execution of image processing corresponding to
the shooting scene at the time of shooting, that is, the image
quality adjustment reflecting the photographer's intention.
[0095] The personal computer PC functioning as the image processing
apparatus of the embodiment selectively executes an adequate series
of image processing among the three options discussed above
according to the image file GF. This arrangement ensures execution
of the most adequate image quality adjustment well reflecting the
photographer's intention and enables a greater number of image
files GF to be subjected to the desired image quality
adjustment.
[0096] The procedure of the above embodiment utilizes either the
information for specifying the image processing mode GM or the
shooting mode described as the Exif information to specify the
image processing mode GM, based on whether the information for
specifying the image processing mode GM is included in the image
processing control information GI. One possible modification may
utilize either the information for specifying the image processing
mode GM or the shooting mode described as the Exif information to
specify the image processing mode GM, in response to the user's
selection. This modified arrangement ensures execution of image
processing that adequately reflects the user's intention.
[0097] The procedure of the above embodiment adopts the image
processing mode GM corresponding to the image processing control
information GI. One possible modification provides an image
processing mode GM' corresponding to the shooting mode, in addition
to the image processing mode GM corresponding to the image
processing control information GI, and executes image processing,
in response to the user's selection, either in the image processing
mode GM corresponding to the information for specifying the image
processing mode GM or in the image processing mode GM'
corresponding to the shooting mode described as the Exif
information. This arrangement ensures execution of adequate image
processing that well reflects the user's intention.
[0098] When the image processing control information GI does not
include the information for specifying the image processing mode
GM, the procedure executes image quality adjustment in the image
processing mode GM, which is selected corresponding to the shooting
mode described as the Exif information. This arrangement ensures
image quality adjustment corresponding to the selected shooting
mode, that is, image processing that well reflects the
photographer's intention.
[0099] In the structure of the above embodiment, the personal
computer PC functioning as the image processing apparatus executes
the whole series of image processing and outputs the processed
image data to the color printer 20. In one modified structure, the
color printer 20 may execute, without the assistant of the personal
computer PC, all or part of the image processing and create a dot
pattern according to the processed image data GD on a printing
medium. The computer may assist the execution. In such
modification, the color printer 20 has the image processing
functions discussed above with reference to FIGS. 8 through 11. The
image file GF generated by the digital still camera 12 is directly
transmitted to the color printer 20 via the cable or via the memory
card MC. The image processing program is automatically activated in
response to detection of insertion of the memory card MC or in
response to detection of attachment of the cable, to automatically
perform input of the image file GF, retrieval of the image
processing control information GI and the Exif information,
conversion of the image data GD, and image quality adjustment.
Another possible modification provides an auto image quality
adjustment button on the operation panel of the color printer 20.
The auto image quality adjustment process discussed in the above
embodiment may be executed only in the case of selection of an auto
image quality adjustment mode through the operation of the auto
image quality adjustment button.
[0100] In the structure of the above embodiment, the color printer
20 is used as the output device. The output device may be a display
device, such as a CRT, an LCD, or a projector. In such cases, the
display device functioning as the output device executes an image
processing program (display driver) to implement the image
processing described above with reference to FIGS. 8 through 11.
When the CRT or the like functions as a display device of the
computer, the computer executes the image processing program. Here
the eventually output image data has the RGB color space, instead
of the CMYK color space.
[0101] The resulting display on the display device, such as the
CRT, reflects the image processing control information GI, as the
resulting print by the color printer 20 reflects the information
obtained at the time of generating the image data. This arrangement
ensures accurate display of the image data GD generated by the
digital still camera 12.
[0102] The embodiment regards the image file complying with the
Exif file format as a concrete example of the image file GF. The
image processing apparatus of the invention is, however, not
restricted to processing of the image files of this format, but is
also applicable to processing of the image files GF complying with
the JFIF file format and those complying with the TIFF file format.
The image file processible by the image processing apparatus of the
invention is required to include the image data GD and at least
either of the image processing control information GI and the Exif
information related to the image data GD.
[0103] In the embodiment discussed above, the personal computer PC
and the color printer 20 are only illustrative and are not
restricted to the structure discussed above. The personal computer
PC and the color printer 20 are required to have at least the
functions of retrieving the image processing control information GI
or the Exif information in the image file GF, which may store both
of the image processing control information GI and the Exif
information, selecting the image processing mode GM based on the
retrieved information, carrying out auto image quality adjustment
in the selected image processing mode GM, and outputting (printing)
the processed image.
[0104] In the structure of the above embodiment, the image data GD
and the image processing control information GI are included in the
identical image file GF. The image data GD and the image processing
control information GI may not be stored in an identical file. The
requirement is that the image data GD is related to the image
processing control information GI. One possible modification
generates mapping data to relate the image data GD to the image
processing control information GI, stores one or multiple image
data GD and the image processing control information GI in separate
files, and refers to the image processing control information GI
related to the image data GD at the time of processing the image
data GD. In this modified structure, the image data is inseparably
integrated with the image processing control information GI in the
course of image processing with the image processing control
information GI. This gives the substantially equivalent functions
to those attained by storage in the identical file. The technique
is also applicable to video files stored in optical disk media,
such as CD-ROMs, CD-Rs, DVD-ROMs, and DVD-RAMs.
[0105] The image processing apparatus and the image processing
method of the invention are described above with reference to some
embodiments. These embodiments are to be considered in all aspects
as illustrative and not restrictive. There may be many
modifications, changes, and alterations without departing from the
scope or spirit of the main characteristics of the present
invention. All changes within the meaning and range of equivalency
of the claims are therefore intended to be embraced therein.
* * * * *