U.S. patent application number 11/531319 was filed with the patent office on 2007-07-05 for gain calculating device.
Invention is credited to Kazunobu Takahashi, Sumito Yoshikawa.
Application Number | 20070154203 11/531319 |
Document ID | / |
Family ID | 38224536 |
Filed Date | 2007-07-05 |
United States Patent
Application |
20070154203 |
Kind Code |
A1 |
Takahashi; Kazunobu ; et
al. |
July 5, 2007 |
GAIN CALCULATING DEVICE
Abstract
A more preferable WB gain is calculated during strobe
illuminated photography. When a WB gain for an image captured
through strobe illuminated photography is calculated, the degree of
contribution of strobe light is first estimated. When the degree of
contribution is estimated, the image is first divided into a
plurality of blocks, and typical brightness values and typical
color values of the respective blocks are determined (S23).
Subsequently, the highest-brightness block among the blocks
analogous to the color of strobe light is identified as a strobe
color block (S26). When there is a strobe color block, the degree
of contribution of strobe light is estimated on the basis of the
position of the strobe color block, a difference between the
brightness of the strobe color block and the brightnesses of other
blocks, and the like (S32 to S48). Meanwhile, when there is no
strobe color block, the degree of contribution is estimated on the
basis of the position of the highest-brightness block having the
highest typical brightness value among the plurality of blocks
(S28, S30).
Inventors: |
Takahashi; Kazunobu;
(Kanagawa, JP) ; Yoshikawa; Sumito; (Kanagawa,
JP) |
Correspondence
Address: |
Pamela R. Crocker;Patent Legal Staff
Eastman Kodak Company, 343 State Street
Rochester
NY
14650-2201
US
|
Family ID: |
38224536 |
Appl. No.: |
11/531319 |
Filed: |
September 13, 2006 |
Current U.S.
Class: |
396/213 ;
348/E5.035; 348/E5.038; 348/E9.052 |
Current CPC
Class: |
G03B 7/16 20130101; H04N
5/2354 20130101; H04N 9/735 20130101; H04N 5/2351 20130101 |
Class at
Publication: |
396/213 |
International
Class: |
G03B 7/00 20060101
G03B007/00 |
Foreign Application Data
Date |
Code |
Application Number |
Jan 5, 2006 |
JP |
2006-831 |
Claims
1. A gain calculating device for calculating a white balance gain
at least for an image captured through strobe illuminated
photography, the device comprising: a block dividing unit for
dividing the image captured through strobe illuminated photography
into a plurality of blocks; an identification unit for identifying,
from among the divided blocks, a highly-influenced block, which is
a block presumed to have been greatly influenced by strobe light; a
first estimation unit for estimating, as a degree of first
contribution, a degree of contribution of strobe light on the basis
of at least one of the position of the highly-influenced block and
a difference between brightness of the highly-influenced block and
brightness of other blocks; and a gain calculating unit for
calculating a white balance gain from at least the degree of first
contribution.
2. The gain calculating device according to claim 1, wherein the
block dividing unit divides an image captured through strobe
illuminated photography into a plurality of blocks and calculates
typical values of brightness of the respective divided blocks as
typical brightness values; and the identification unit identifies,
as a highly-influenced block, a block having a large typical
brightness value among the divided blocks.
3. The gain calculating device according to claim 1, wherein the
block dividing unit divides an image captured through strobe
illuminated photography into a plurality of blocks and calculates
typical values of color values of the respective divided blocks as
typical color values; and the identification unit identifies, as a
highly-influenced block, a block having a typical color value close
to the color of strobe light among the blocks.
4. The gain calculating device according to claim 3, wherein the
block dividing unit calculates typical values of brightness of the
respective divided blocks as typical brightness values; and the
identification unit identifies, as a highly-influenced block, a
block having a large typical brightness value among the blocks
having typical color values close to the color of strobe light.
5. The gain calculating device according to claim 3 or 4, wherein a
first estimation unit estimates the degree of contribution of
strobe light on the basis of at least a difference between a
typical brightness value of a highly-influenced block and a typical
brightness value of the highest-brightness block having a high
typical brightness value among other blocks.
6. The gain calculating device according to claim 1, wherein a
first estimation unit estimates the degree of contribution of
strobe light on the basis of at least the position of a
highly-influenced block.
7. The gain calculating device according to claim 6, wherein a
first estimation unit calculates the degree of contribution of
strobe light as a smaller value with increasing distance of the
highly-influenced block from an area where a main subject is
presumed to be present.
8. The gain calculating device according to claim 7, wherein the
area where a main subject is presumed to be present is one of in
the vicinity of a center of an image or at an AF detection point
designated by a user.
9. The gain calculating device according to claim 7 or 8, wherein
the size of the area where a main subject is presumed to be present
is changed on the basis of at least one of a zooming factor and a
distance to a subject.
10. The gain calculating device according to claim 1, wherein a
first estimation unit estimates the degree of contribution of
strobe light on the basis of at least a difference between a
typical brightness value of a highly-influenced block and a mean
brightness value of a plurality of blocks estimated to be
comparatively unexposed to strobe light.
11. The gain calculating device according to claim 10, wherein the
plurality of blocks estimated to be comparatively unexposed to
strobe light correspond to either blocks located around the center
of an image, blocks located around an AF detection point designated
by a user, or blocks located around the highly-influenced
block.
12. The gain calculating device according to any one of claims 1
through 11, further comprising: a second estimation unit for
estimating the degree of contribution of strobe light as the degree
of second contribution on the basis of a distance to a subject; and
a gain calculating unit for calculating a white balance gain on the
basis of at least the degree of first contribution and the degree
of second contribution.
13. The gain calculating device according to any one of claims 1
through 12, further comprising: a third estimation unit for
estimating the degree of contribution of strobe light as the degree
of third contribution on the basis of a difference between
environment brightness achieved before firing of strobe light and
environment brightness achieved at the time of firing of strobe
light; and gain calculating unit for calculating a white balance
gain on the basis of at least the degree of first contribution and
the degree of third contribution.
14. A gain calculating device for calculating a white balance gain
at least for an image captured through strobe illuminated
photography, the device comprising: a first brightness acquisition
unit for acquiring environment brightness achieved before firing of
strobe light as prefiring brightness; a second brightness
acquisition unit for acquiring environment brightness achieved at
the time of firing of strobe light as firing brightness; an
estimation unit for estimating, as the degree of third
contribution, the degree of contribution of strobe light on the
basis of a difference between the prefiring brightness and the
firing brightness; and a calculating unit for calculating a white
balance gain on the basis of at least the degree of third
contribution.
15. The gain calculating device according to claim 14, wherein the
first brightness acquisition unit acquires, as prefiring
brightness, a mean brightness value of a preview image acquired
before firing of strobe light.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application claims priority to Japanese Patent
Application No. 2006-831 filed on Jan. 5, 2006, which is
incorporated herein by reference in its entirety.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to a gain calculating device
for calculating a white balance gain suitable for at least an image
captured through strobe illuminated photography.
[0004] 2. Related Art
[0005] In the field of cameras, there has been widely known a white
balance technique for correcting the color of a captured image
according to the type of a light source employed at the time of
capture of the image, and the like. This technique is an image
processing technique for eliminating a discrepancy between an
impression which a photographer had during photographing action and
an impression given by an output image, which is caused by the
color of the light source employed during photography.
[0006] A technique for taking into consideration, during such white
balance processing, whether or not strobe light has been fired
during photographing action has hitherto been known. For instance,
Japanese Patent Laid-Open Publication No. 2000-92509 describes
calculation of a white balance gain by use of a strobe standard
value previously set for strobe illuminated photography upon
notification of firing of a strobe light. According to this
technique, a strobe standard value is always constant, regardless
of the degree of contribution of strobe light to a subject.
Therefore, when strobe light has not sufficiently reached the
subject or when strobe light has been radiated with excessive
intensity on the subject, there arises a problem of a failure to
compute an appropriate white balance gain.
[0007] Accordingly, there has hitherto been practiced a technique
of estimating, during strobe illuminated photography, the degree of
contribution of strobe light, the degree of contribution of an
ambient light source, the degree of contribution of strobe light,
and the like; and adjusting a white balance gain according to the
thus-estimated degrees of contribution and the like. For instance,
Japanese Patent Laid-Open Publication No. Hei-4-326888 describes a
technique for determining whether or not strobe light reaches a
subject, on the basis of a distance to the subject. When the strobe
light is determined not to be able to reach the subject, a preset
value of a white balance is made selectable. Further, Japanese
Patent Laid-Open Publication No. 2003-244467 describes a technique
of detecting an area where a degree of mixing of ambient light and
flash light is larger than a predetermined value, on the basis of
information about ambient light existing during photographing
action (the type of an ambient light source and the like),
information about flash light employed during photographing action
(presence/absence of flash light, the intensity of flash-reflected
light, and the like), and the like. On the basis of a ratio of the
detected area to the entire area, specifics of image processing,
such as white balance processing, and the like, are determined.
According to these conventional techniques, even when an image has
been photographed by strobe light, the degree of mixing of strobe
light (i.e., the degree of contribution of strobe light) is taken
into consideration. Hence, a comparatively-appropriate white
balance gain can be acquired.
[0008] However, any of these conventional techniques involves
estimating the degree of contribution of strobe light from
information extracted from factors other than a captured image such
as a distance to a subject and information about flash light.
Therefore, the conventional techniques cannot be said to have a
high degree of precision in estimating the degree of contribution
of strobe light. The low degree of precision in estimating the
degree of contribution of strobe light poses difficulty in
performing white balance processing suitable for strobe illuminated
photography.
SUMMARY OF THE INVENTION
[0009] Accordingly, the present invention provides a gain
calculating device capable of calculating a white balance gain
suitable for strobe illuminated photography.
[0010] The present invention provides a gain calculating device for
calculating a white balance gain at least for an image captured
through strobe illuminated photography, the device comprising:
[0011] a block dividing unit for dividing the image captured
through strobe illuminated photography into a plurality of
blocks;
[0012] an identification unit for identifying, from among the
divided blocks, a highly-influenced block; i.e., a block presumed
to have been greatly influenced by strobe light;
[0013] first estimation unit for estimating, as a degree of first
contribution, a degree of contribution of strobe light on the basis
of at least one of the position of the highly-influenced block and
a difference between brightness of the highly-influenced block and
brightness of other blocks; and
[0014] a gain calculating unit for calculating a white balance gain
from at least the degree of first contribution.
[0015] In a preferred mode, the block dividing unit divides an
image captured through strobe illuminated photography into a
plurality of blocks and calculates typical brightness values of the
respective divided blocks as typical brightness values; and the
identification unit identifies, as a highly-influenced block, a
block among the divided blocks having a large typical brightness
value.
[0016] In another preferred mode, the block dividing unit divides
an image captured through strobe illuminated photography into a
plurality of blocks and calculates typical values of color values
of the respective divided blocks as typical color values; and the
identification unit identifies, as a highly-influenced block, a
block among the divided blocks having a typical color value close
to the color of strobe light. In this case, the block dividing unit
preferably calculates typical brightness values of the respective
divided blocks as typical brightness values; and the identification
unit preferably identifies, as a highly-influenced block, a block
having a large typical brightness value having typical color values
close to the color of strobe light among the blocks.
[0017] In still another preferred mode, a first estimation unit
estimates the degree of contribution of strobe light on the basis
of at least a difference between a typical brightness value of a
highly-influenced block and a typical brightness value of the
highest-brightness block having a high typical brightness value
among other blocks.
[0018] In yet another preferred mode, a first estimation unit
estimates the degree of contribution of strobe light on the basis
of at least the position of a highly-influenced block. In this
case, a first estimation unit preferably calculates the degree of
contribution of strobe light as a smaller value with increasing
distance of the highly-influenced block from an area where a main
subject is presumed to be present. Further, an area where a main
subject is presumed to be present is preferably at least in the
vicinity of a center of an image or at an AF detection point
designated by a user. The size of an area where a main subject is
presumed to be present is preferably changed on the basis of at
least one of a zooming factor and a distance to a subject.
[0019] In still another preferred mode, a first estimation unit
estimates the degree of contribution of strobe light on the basis
of at least a difference between a typical brightness value of a
highly-influenced block and a mean brightness value of a plurality
of blocks estimated to be comparatively unexposed to strobe light.
In this case, the plurality of blocks estimated to be comparatively
unexposed to strobe light preferably correspond to either of blocks
located around the center of an image, blocks located around an AF
detection point designated the user, or blocks located around the
highly-influenced block.
[0020] In yet another preferred mode, the gain calculating device
further comprises a second estimation unit for estimating the
degree of contribution of strobe light as the degree of second
contribution on the basis of a distance to a subject; and gain
calculating unit for calculating a white balance gain on the basis
of at least the degree of first contribution and the degree of
second contribution. In another preferred mode, the gain
calculating device further comprises a third estimation unit for
estimating the degree of contribution of strobe light as the degree
of third contribution on the basis of a difference between
environment brightness achieved before firing of strobe light and
environment brightness achieved after firing of strobe light; and
gain calculating unit for calculating a white balance gain on the
basis of at least the degree of first contribution and the degree
of third contribution.
[0021] The present invention also provides a gain calculating
device for calculating a white balance gain at least for an image
captured through strobe illuminated photography, the device
comprising:
[0022] a first brightness acquisition unit for acquiring
environment brightness achieved before firing of strobe light as
prefiring brightness;
[0023] a second brightness acquisition unit for acquiring
environment brightness achieved at the time of firing of strobe
light as firing brightness;
[0024] an estimation unit for estimating, as the degree of third
contribution, the degree of contribution of strobe light on the
basis of a difference between the prefiring brightness and the
firing brightness; and
[0025] a calculating unit for calculating a white balance gain on
the basis of at least the degree of third contribution. In this
case, the first brightness acquisition unit desirably acquires, as
prefiring brightness, a mean brightness value of a preview image
acquired before firing of strobe light.
[0026] According to the present invention, the degree of
contribution of strobe light is assumed on the basis of an
actually-captured image, and hence a highly-reliable degree of
contribution of strobe light is obtained. Consequently, a more
preferable white balance gain can be obtained.
[0027] The invention will be more clearly comprehended by reference
to the embodiments provided below. However, the scope of the
invention is not limited to those embodiments.
BRIEF DESCRIPTION OF THE DRAWINGS
[0028] Preferred embodiments of the present invention will be
described in detail based on the following figures, wherein:
[0029] FIG. 1 is a block diagram showing the configuration of a
digital camera which is an embodiment of the present invention;
[0030] FIG. 2 is a flowchart showing flow of calculation of a WB
gain;
[0031] FIG. 3 is a view showing an example result of determination
of a light source;
[0032] FIG. 4 is a view showing an example reference gain
table;
[0033] FIG. 5 is a flowchart showing flow of calculation of the
degree of a first contribution;
[0034] FIG. 6 shows an example table of the degree of tentative
contribution according to a position;
[0035] FIG. 7 shows an example peripheral block;
[0036] FIG. 8 is a view showing an example function between a
distance to a subject and the degree of second contribution;
[0037] FIG. 9 is a view showing an example function between the
degree of third contribution and a difference between environment
brightness achieved before firing of strobe light and that achieved
after firing of strobe light; and
[0038] FIG. 10 is a view showing an example result of determination
of a light source.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0039] An embodiment of the present invention will be hereinbelow
described by reference to the drawings. FIG. 1 is a block diagram
showing the configuration of a digital camera 10 which is an
embodiment of the present invention. Light from a field
(hereinafter simply called "light"), which has entered by way of an
aperture member 12 and a lens 14, comes into a focus on a CCD 16,
which is an image-capturing device. The amount of opening of the
aperture member 12 and the amount of movement of the lens 14 are
controlled by a CPU 48. The CCD 16 converts the input light into an
electrical signal, and outputs the thus-converted electrical signal
as captured-image data. Timing at which the CCD 16 performs
photoelectric conversion is controlled by the CPU 48 via a timing
generator (TG) 36. The CCD 16 always stores and sweeps electric
charges at given intervals in order to acquire a preview image to
be displayed on an LCD 34. Moreover, when a user's command for
capturing an image is input, photoelectric conversion for acquiring
a preview image is temporarily interrupted. After electric charges
have been accumulated with elapse of an exposure time required to
capture an actual image, electric charges are swept.
[0040] An electric signal output from the CCD 16 is converted into
digital data by unit of an analog-to-digital (A/D) converter 22
after having undergone predetermined analogue signal processing
performed by a correlated double sampling (CDS) circuit 18 and
amplification processing performed by an amplifying (AMP) circuit
20. The digital data are temporarily stored as image data in image
memory 24.
[0041] The image data temporarily stored in the image memory 24 are
output to an image processing section 25 and a WB (White Balance)
gain acquisition section 51. In the image processing section 25, an
RGB separation section 26 separates the image data into three color
components; an R component, a G component, and a B component. The
separated data are sequentially sent to a WB processing section 28,
a .gamma. correction section 30, and a color correction section 32,
where the data are subjected to predetermined image processing. Of
these sections, the WB processing section 28 multiplies
corresponding color component data by three types of WB gains
computed by the WB gain acquisition section 51, which will be
described later; namely, an R gain, a G gain, and a B gain, thereby
performing WB processing.
[0042] The image data having undergone image processing are output
to the LCD 34 and image memory 40. A memory controller 38 controls
driving of the image memory 40 and the previously-described image
memory 24. The LCD 34 electrically displays the image data having
undergone image processing. The image data displayed on the LCD 34
include a preview image and a captured image recorded in a
recording medium 44 to be described later. When the preview image
is displayed, the LCD 34 acts as an electric finder which displays
images in a field (hereinafter simply called "images") that can be
captured. When a captured image recorded in the recording medium 44
is displayed, the LCD 34 functions as a playback monitor for
playing back and displaying a captured image.
[0043] The image data temporarily stored in the image memory 40 are
subjected to compression processing performed by a
compression-and-expansion circuit 42, and the thus-compressed image
data are recorded in the recording medium 44. The image data
recorded in the recording medium 44 are subjected to expansion
processing performed by the compression-and-expansion circuit 42 in
accordance with a command from the user, and the thus-expanded data
are displayed on the LCD 34. Upon glancing at a display on the LCD
34, the user can ascertain details of the captured image. An
operation section 58 is an interface which receives a command from
the user. The CPU 48 controls driving of individual sections in
accordance with the user command input via the operation section
58.
[0044] A strobe device 46 fires strobe light toward a field in
order to compensate for a deficiency in the amount of light of the
field. Firing timing of the strobe device 46 and the amount of
light fired by the strobe light 46 are controlled by an
AE/AF/strobe control section 50.
[0045] The AE/AF/strobe light control section 50 calculates
environment brightness and a distance to a subject from a value
detected by an unillustrated AE sensor, a value detected by a range
sensor, the amount of zoom designated by the user, and the like,
thereby calculating exposure, the amount of movement of the lens
14, firing timing of a strobe, the amount of radiated light, and
the like. The timing of the TG 36 is controlled on the basis of the
obtained amount of exposure, and the like; and driving the lens 14
is controlled according to the amount of actuation of the lens.
Further, the strobe device 46 is controlled on the basis of the
timing of firing of strobe light and the amount of fired light.
[0046] The WB gain acquisition section 51 calculates a WB gain used
for previously-described WB gain processing. The WB gain
acquisition section 51 is roughly divided into a
degree-of-contribution computing section 52 and a gain computing
section 56. The gain computing section 56 computes a WB gain from
the captured image data and a reference gain table stored in the
memory. When an image is captured through strobe illuminated
photography, a WB gain is calculated in consideration of the degree
of contribution of the strobe light calculated by the
degree-of-contribution computing section 52. When an image is
captured through strobe illuminated photography, the
degree-of-contribution computing section 52 estimates the degree of
contribution of strobe light to the field. Calculation of the WB
gain and flow of calculation of the degree of contribution will be
described in detail later.
[0047] Respective main programs and data, which are required to
control the digital camera 10, are stored in memory 54. A gain
table; i.e. a table of reference gain values which are required to
calculate a WB gain according to the type of a light source, is
also set in the memory 54. The previously-described WB gain
computing section 56 computes a WB gain by reference to a reference
gain table stored in the memory 54. This reference gain table will
also be described in detail later.
[0048] There will now be described the flow of calculation of a WB
gain performed by the digital camera 10. FIG. 2 is a flowchart
showing the flow of calculation of a WB gain. When a WB gain is
computed, a determination is first made, during photography of an
image, as to whether or not strobe light has been fired (S10).
Firing/nonfiring of strobe light can be determined on the basis of
a control signal output from the AE/AF/strobe control section 50.
When strobe light has not been fired, a WB gain is calculated
through ordinary WB gain calculation processing (S12). Various
known techniques can be utilized for the flow of calculation of a
WB gain, and hence will be described briefly herein.
[0049] When a WB gain of an image for which strobe light has not
been fired is calculated, a captured image is first divided into a
plurality of blocks, and a typical color value and a typical
brightness value, both belonging to each of the blocks, are
computed as a typical color value and a typical brightness value.
The type of a light source of each block is specified on the basis
of the thus-obtained typical color value of the block. The degrees
of reliability of the respective blocks are also calculated from
the brightness values and the like. As long as the type of the
light source and the degree of reliability can have been
calculated, a value is added to the degree of reliability of each
block according to the type of the light source, and the thus-added
value is taken as a weighting coefficient for the type of a light
source. For instance, the light sources of respective blocks are
assumed to be determined as shown in FIG. 3. In FIG. 3, reference
symbol Dy denotes a block determined to have been exposed to
daylight; Fl denotes a block determined to have been exposed to
fluorescent light; and Tn denotes a block determined to have been
exposed to tungsten light. For the sake of brevity, the degrees of
reliability of all blocks are presumed to assume a value of one. In
this case, the weighting coefficient of daylight corresponds to the
number of daylight blocks; namely, four. Similarly, the weighting
coefficient of fluorescent light assumes a value of three, and the
weighting coefficient of tungsten light assumes a value of
three.
[0050] As long as the weighting coefficient have been calculated,
there is determined a weighted mean value of the reference gain
values set in the reference gain table for respective types of
light sources and the weighting coefficients. As shown in FIG. 4,
the reference gain table is one where appropriate reference gain
values are set according to the type of light source. In FIG. 4,
reference symbol Gs denotes a reference gain value of strobe light;
Gd denotes a reference gain value of daylight; Gt denotes a
reference gain value of tungsten light; and Gf denotes a reference
gain value of light of a fluorescent lamp. In FIG. 4, the reference
gain values for respective types of light sources are represented
as coordinates in a color space called a T space. When the color
expressed by an RGB value is converted into coordinates in the T
space, the following formula is employed.
( Tl Tg Ti ) = ( 1 / 4 1 / 2 1 / 4 - 1 / 4 1 / 2 - 1 / 4 - 1 / 2 0
1 / 2 ) ( R G B ) ##EQU00001##
where T1 denotes the brightness of a block, and Tg, Ti denote color
differences among blocks. In T space, a color is expressed while Tg
is taken as the vertical axis and Ti is taken as the horizontal
axis. The matrix of linear conversion employed herein is a mere
example, and another matrix may also be employed.
[0051] When a WB gain is calculated, there is determined a weighted
mean value between reference gain values of light sources of
respective types expressed as coordinates in the T space and
weighting coefficients of the light sources of respective types
calculated on the basis of the captured image. This weighted mean
value represents coordinates in the T space. A WB gain is obtained
by converting, into an RGB value, the weighted mean value
corresponding to the coordinates in the T space. In the embodiment
shown in FIG. 3, the weighted mean value is determined by means of
(4Gd+3Gt+3Gf)/7. The thus-calculated coordinates in the T space are
converted into an RGB value, whereby a WB gain is obtained.
[0052] As mentioned above, when strobe light has not been fired, a
WB gain is calculated on the basis of the captured image and the
reference gain table. Meanwhile, when strobe light has been fired,
the degree of contribution of strobe light is estimated (S14, S16,
S18) and is used to calculate the WB gain (S20, S22). The degree of
contribution assumes a range from zero to one. The greater the
degree of contribution of strobe light, the more closely the degree
approaches one. Flow of calculation of the degree of contribution
will be sequentially described. When strobe illuminated photography
has been performed, the degree of first contribution BSC is first
calculated on the basis of information contained in a captured
image (S14).
[0053] FIG. 5 is a flowchart showing flow of calculation of the
degree of first contribution BSC. The degree of first contribution
BSC is an estimation of the degree of contribution of strobe light
on the basis of whether or not an intensively-exposed area, which
has been intensively exposed to strobe light, is present in the
captured image. Specifically, the captured image is first divided
into a plurality of blocks, and typical values of brightness values
and typical color values of the respective blocks are calculated as
a typical brightness value and a typical color value (S23).
[0054] Subsequently, the highest-brightness block and a strobe
color block are identified (S24). The highest-brightness block is a
block having the highest typical brightness value among a plurality
of blocks. Consequently, the highest-brightness block can be
identified by means of comparing typical brightness values of the
respective blocks with each other. Meanwhile, a strobe color block
corresponds to a highly-influenced block that is presumed to be
most significantly influenced by strobe light. Of one or more
blocks having typical color values analogous to the color of strobe
light, a block having the largest typical brightness value is the
strobe color block. Consequently, when the strobe color block is
specified, blocks having typical color values analogous to the
color of strobe light are identified from among the plurality of
blocks. Since the color of strobe light is known, the essential
requirement is to identify blocks having typical color values which
differ from the known color within a predetermined allowable range.
Of the thus-identified blocks, a block having the highest typical
brightness value is taken as a strobe color block. This strobe
color block can be presumed to be an area in the captured image,
which has been intensively exposed to strobe light; namely, an
intensively-exposed area. At this point in time, the strobe color
block is identified from only the brightness values and the color
values. Hence, a definite determination cannot be made as to
whether or not the strobe color block (the highly-influenced block)
is a actual intensively-exposed area. Accordingly, the degree of
contribution is calculated from the position of the strobe color
block and a difference between the brightness of the strobe color
block and the brightnesses of the other blocks.
[0055] There may be a case where the block having the highest
typical brightness value and the block having the highest typical
color value among the blocks having typical color values close to
the color of strobe light are not single but plural. In this case,
among the plurality of blocks, blocks close to the center of the
image are preferably identified as the highest-brightness blocks
and the strobe color blocks.
[0056] When the strobe color block and the highest-brightness block
are present (S26), the degree of tentative contribution SBW is
calculated from the position of the strobe color block (S32). The
degree of tentative contribution SBW is a value which becomes a
reference for calculation of the degree of first contribution SBC,
and is temporarily calculated.
[0057] In many cases, a main subject is present in the vicinity of
the center of the captured image. When strobe light has been fired,
a neighborhood of the center of the captured image where the main
subject is present is presumed to be most intensively exposed. Put
another way, if the strobe color block is an actual
intensively-exposed area, the strobe color block is likely to be
located in the vicinity of the center of the captured image.
Conversely, when the strobe color block is located in the vicinity
of an edge of the image, the chance of the strobe color block being
an intensively-exposed area is low; and, by extension, the degree
of influence of strobe light being imposed on the field is said to
be low.
[0058] In the present embodiment, the more the actually-identified
strobe color block is distant from the center of the image, the
lower the chance of strobe light having reached a subject is
considered to be, and the degree of tentative contribution SBW is
made small. A table such as that shown in FIG. 6 can be utilized
for calculation of the degree of tentative contribution SBW. FIG. 6
is an example table of the degrees of tentative contribution SBW
appropriate to the positions. In the example table shown in FIG. 6,
the degree of tentative contribution SBW of the most
intensively-colored block is taken as one, and the degree of
tentative contribution SBW of the next intensively-colored block is
taken as 0.8. The degree of tentative contribution SBW of the most
lightly-colored block is taken as 0.5. Such a table has been
prepared in advance, and the locations of the actually-identified
strobe color blocks and the values of the thus-prepared table are
compared with each other, thereby enabling calculation of the
degree of tentative contribution SBW. For instance, the location of
the actually-identified strobe color block is assumed to be B1 in
FIG. 6. In this case, the degree of tentative contribution SBW is
0.8.
[0059] The table of the degrees of tentative contribution SBW
corresponding to the positions may also be changed, as required,
according to the distance to the subject and the zooming factor.
Specifically, the range made up of the main subject reflecting
strobe light is changed, as appropriate, according to the distance
to the subject and the zooming factor. As long as the table of the
degree of tentative contribution is changed according to a change
in the range made up of the main subject, a more reliable degree of
first contribution BSC is considered to be obtained. Some cameras
can designate an AF detection point; namely, a location where focus
is obtained. Such cameras may be provided with a table where the
degree of tentative contribution SBW becomes smaller as a distance
between a block and the AF detection point designated by the user
increases.
[0060] When the degree of tentative contribution SBW has been
obtained, the typical brightness value MBL of the
highest-brightness block is compared with the typical brightness
value SBL of the strobe color block, thereby determining a
difference between the brightnesses (S34). There is a high chance
of the brightness of an area intensively exposed to strobe light;
namely, the brightness of an intensively-exposed area, becoming
highest in the captured image. Put another way, when the typical
brightness value SBL of the strobe color block is highest in the
captured image, the strobe color block can be said to be an
intensively-exposed area with high possibility. The degree of
contribution of strobe light can also be presumed to be high.
[0061] Therefore, in the present embodiment, the typical brightness
value MBL of the highest-brightness block is compared with the
typical brightness value SBL of the strobe color block. When the
difference between the typical brightness values of both blocks is
zero; in other words, no difference exists between the typical
brightness values of both blocks, the strobe color block can be
said to be the highest-brightness block in the captured image. In
this case, there is a high possibility of the strobe color block
being an intensively-exposed area, and the degree of contribution
of strobe light can be presumed to be high. Accordingly, in the
case of MBL=SBL, the previously-calculated degree of tentative
contribution SBW is set as the degree of first contribution BSC
(S36).
[0062] Meanwhile, when the typical brightness value SBL of the
strobe color block is smaller than the typical brightness value MBL
of the highest-brightness block, the chance of the strobe color
block being an intensively-exposed block is considered to be low.
When a point light source having high brightness is coincidentally
present in the field and when the area of the point light source
has been identified as the highest-brightness block, the chance of
the strobe color block being the intensively-exposed block cannot
necessarily be said to be low. There is a sufficient possibility of
a point light source, which is higher than the strobe light in
terms of brightness, having been identified as the
highest-brightness block regardless of the strobe light having
sufficiently reached the field.
[0063] When the typical brightness value SBL of the strobe color
block is smaller than the typical brightness value MBL of the
highest-brightness block (MBL>SBL), an additional determination
is made as to whether or not the strobe color block is an
intensively-exposed area. Specifically, processing proceeds to step
S38, where a determination is made as to whether or not the
difference between the typical brightness values falls within a
predetermined allowable range X. When the difference between the
typical brightness values is comparatively large and when the
difference is out of the predetermined allowable range
(MBL-SBL>X), the chance of the strobe color block being an
intensively-exposed block can be said to be low. In this case, the
degree of contribution of strobe light is presumed to be low, and
hence a value determined by rendering significantly small the
previously-calculated degree of tentative contribution SBW; e.g., a
value of one-fifth of the degree of tentative contribution SBW, is
calculated as the degree of first contribution BSC (S48).
[0064] Meanwhile, when a difference between the typical brightness
value MBL of the highest-brightness block and the typical
brightness value SBL of the strobe color block is comparatively
small and when the difference falls within a predetermined
allowable range (MBL-SBL.ltoreq.X), an average brightness level AL
of peripheral blocks is calculated (S40). The term "peripheral
blocks" means a plurality of blocks which are comparatively
unexposed to strobe light. As mentioned previously, the main
subject is presumed to be intensively exposed to strobe light, and
the main subject is presumed to be located in the vicinity of the
center of the captured image. Consequently, the blocks which are
comparatively unexposed to strobe light are presumed to be located
at positions slightly away from the center of the captured image;
e.g., locations hatched in FIG. 7. In the present embodiment,
positions of such peripheral blocks have previously been predicted,
and an average value of typical brightness values of the predicted
blocks is calculated as an average brightness value AL of the
peripheral blocks. Identifying a plurality of blocks are identified
as peripheral blocks and calculating the average brightness level
AL of the blocks are intended for lessening the influence of the
point light source. Specifically, when only a single block is
identified as a peripheral block, there may arise a case where the
area of a point light source, which is coincidentally present, is
identified as single peripheral block. In this case, the periphery
of the main subject is erroneously ascertained as high brightness.
However, as a result of a plurality of blocks being identified and
a mean brightness value of the blocks being calculated, the
influence of such a point light source can be lessened.
[0065] As long as the average brightness value AL of the peripheral
blocks can be calculated, the average brightness value AL of the
peripheral blocks and the typical brightness value SBL of the
strobe color block are compared with each other (S42).
Consequently, when the typical brightness value SBL of the strobe
color block is greater than the calculated average brightness level
AL of the peripheral blocks, a sufficient chance of the strobe
color block being an intensively-exposed block can be said to be.
In this case, a value of four-fifth of the calculated degree of
tentative contribution SBW is calculated as the degree of first
contribution BSC (S44).
[0066] When the typical brightness value SBL of the strobe color
block is smaller than the average brightness value AL of the
peripheral blocks, the chance of the strobe color block being an
intensively-exposed block is said to be low. In this case, a value
of two-fifth of the calculated degree of tentative contribution SBW
is calculated as the degree of first contribution BSC (S46).
[0067] The position and size of the peripheral blocks may be
changed as appropriate. Specifically, as mentioned previously, the
area made up of the main subject changes according to the distance
to the subject, the zooming factor, and the like. Consequently,
changes in the positions and sizes of peripheral blocks which are
comparatively unexposed to strobe light can be predicted.
Accordingly, the positions and sizes of the peripheral blocks may
be changed, as appropriate, according to the distance to a subject,
the zooming factor, and the like. Moreover, when the user has
designated the AF point, the positions of the peripheral blocks may
be changed according to the designated point. In the present
embodiment, the positions of the peripheral blocks are determined
on the assumption that the main subject is present in the vicinity
of the center of the image. However, the positions of the
peripheral blocks may be determined on the assumption that the main
subject is present around the strobe color block. Specifically,
blocks located at positions slightly distant from the strobe color
block may be taken as peripheral blocks.
[0068] Incidentally, all of the above-described flows are for the
case where the strobe color block; namely, a block having a color
analogous to that of strobe light, is present. However, there may
be a case where a block analogous to the color of strobe light is
not present at all in a captured image. In such a case, the
highest-brightness block is presumed to be an area intensively
exposed to strobe light, the degree of first contribution BSC is
calculated. Namely, in step S24, when, even if an attempt is made
to identify a strobe color block, such a block is not present,
processing proceeds to step S28. In step S28, the degrees of
tentative contribution SBW are calculated on the basis of the
position of the highest-brightness block. As in the case of step
S32, the degrees of tentative contribution SBW are calculated in
advance in accordance with the table where the degrees of tentative
contribution SBW are set according to a position such as that shown
in FIG. 6. The table shown in FIG. 6 is compared with the position
of the identified highest-brightness block, thereby calculating the
degree of tentative contribution SBW.
[0069] As long as the degree of tentative contribution SBW has been
calculated on the basis of the position of the highest-brightness
block, a value of one-half of the degree of tentative contribution
SBW is calculated as the degree of first contribution BSC (S30).
The reason why the degree of tentative contribution SBW is taken as
one-half is because the possibility of the highest-brightness
blocks being the intensively-exposed areas is high. Specifically,
the intensively-exposed area that is intensively exposed to strobe
light should originally assume a color analogous to the color of
strobe light as well as being highly bright. Meanwhile, the
highest-brightness blocks are highly bright, but colors of some
highest-brightness blocks are not analogous to the color of strobe
light. The possibility of such highest-brightness blocks being
intensively-bright areas can be said to be low. Therefore, when
strobe color blocks are not present, a value of one-half of the
degree of tentative contribution SBW determined from the position
of the highest-brightness block is calculated as the degree of
first contribution BSC.
[0070] The flows of calculation of the degree of first contribution
BSC have been described thus far. As is evident from the above
descriptions, in the present embodiment, the degree of contribution
of strobe light is presumed on the basis of specifics of the
actually-captured image. Consequently, when compared with a
conventional technique of estimating the degree of contribution
from only various photographing conditions; e.g., luminous
brightness of the flash, a distance to a subject, and the like, the
degree of contribution with high reliability can be estimated,
whereby a more preferable WB gain can be obtained.
[0071] Various specific numerals provided in the above
descriptions; e.g., a value of four-fifth in step S44, a value of
two-fifth in step S46, and the like, are mere examples, and can be
changed as appropriate.
[0072] In the present embodiment, the typical brightness value SBL
of the strobe color block is compared with the typical brightness
value MBL of the highly-bright blocks and the average brightness
value AL of the peripheral blocks. As long as a determination can
be made as to whether or not strobe light affects the strobe color
portion of the image, another values may be compared. For instance,
an average or a standard deviation of typical brightness values of
all blocks having typical brightness values close to the color of
strobe light may also be used in lieu of the typical brightness
values SBL of the strobe color blocks. Further, an average value or
a standard deviation of typical brightness values of all blocks
having typical brightness values which are greater than a
predetermined threshold value or top several percentages of blocks
having high typical brightness values, may also be used in place of
the typical brightness value MBL of the highly-bright blocks.
Moreover, a standard deviation of typical brightness values of the
peripheral blocks may also be used in place of the average
brightness value AL of the peripheral blocks.
[0073] In the present embodiment, among blocks having typical color
values analogous to the color of strobe light, a block having the
highest brightness (strobe color blocks) is taken as a block
greatly influenced by strobe light; namely, a highly-influenced
block. More simply, a block having the highest typical brightness
value or a block having a typical color value analogous to the
color of strobe light may be taken as a highly-influenced block.
Among the plurality of divided blocks, a block having the highest
typical brightness value may be identified as a highly-influenced
block, and the degree of first contribution may be determined on
the basis of the position of the highly-influenced block and a
difference between the brightness of the highly-influenced block
and the brightnesses of peripheral blocks. Alternatively, among the
plurality of divided blocks, a block having typical color values
analogous to the color of strobe light may be identified as a
highly-influenced block, and the degree of first contribution may
be estimated from the position of the highly-influenced block, a
difference between the brightness of the highly-influenced block
and the brightnesses of peripheral blocks, and a difference between
the brightness of the highly-influenced block and the brightness of
the highly-bright block. In this case, the strobe light is presumed
to have hardly reached the subject unless there is a block having a
typical color value analogous to the color of strobe light, and it
is better to set the degree of first contribution BSC to a small
value (e.g., 0.1 or the like). When there are a plurality of blocks
having the highest typical brightness value or a plurality of
blocks having typical color values analogous to the color of the
strobe light, a block of the plurality of blocks that is closest to
the center of the image is desirably identified as a
highly-influenced block.
[0074] Turning back to FIG. 2, continued flow of calculation of the
WB gain is now provided. As long as the degree of first
contribution BSC can have been calculated, the degree of second
contribution DW is continuously calculated from the distance to the
subject (S16). The degree of second contribution DW is the degree
of contribution of strobe light presumed on the basis of the
distance to the subject. In general, the greater the distance to
the subject, the smaller the degree of contribution of strobe light
is predicted to become. Accordingly, as shown in FIG. 8, there is
set a function between the distance to the subject and the degree
of second contribution DW, by means of which the degree of second
contribution DW becomes smaller as the distance to the subject
increases. The distance to the subject detected by the range sensor
during capture of an image is applied to the function shown in FIG.
8, to thus determine the degree of second contribution DW.
[0075] When the degree of second contribution DW has been
determined, the degree of third contribution LW is successively
presumed (S18). The degree of third contribution LW is the degree
of contribution of strobe light estimated on the basis of the
amount of difference between the environment brightness achieved
before firing of strobe light and that achieved after firing of
strobe light. In general, when the environment brightness has
greatly changed before and after firing of strobe light, the degree
of contribution of strobe light is considered to be high.
Conversely, when a great change does not arise in environment
brightness, the strobe light is presumed to hardly reach the
subject or to provide the field with no influence. For these
reasons, in the present embodiment, an average brightness value of
the captured image acquired before firing of strobe light and an
average brightness value of the captured image acquired during
firing of strobe light are calculated, and the degree of third
contribution LW is calculated on the basis of the difference in
brightness. A preview image can be used as an image captured before
firing of strobe light. The preview image is captured at given
intervals at all times. Therefore, if, among the preview images, a
preview image captured before firing of strobe light; namely, a
preview image captured before a release switch is depressed all the
way down, is used, an image captured before firing of strobe light
can be obtained.
[0076] As long as the preview image acquired before firing of
strobe light and the image captured during firing of strobe light
are obtained, the average brightness values of the respective
images are calculated, to thus calculate a difference between the
brightness values. The greater the difference in brightness, the
greater the degree of contribution of strobe light is considered to
be. Therefore, the degree of third contribution LW is calculated so
as to become greater with an increase in brightness difference.
Specifically, as shown in FIG. 9, a function--by means of which the
degree of third contribution LW becomes greater with an increase in
brightness difference--is set in advance. A difference between the
average brightness value of the preview image and that of the image
captured through strobe illuminated photography is applied to the
function shown in FIG. 9, thereby calculating the degree of third
contribution LW.
[0077] Like the degree of first contribution BSC, the degree of
third contribution LW is the degree of contribution which is
actually calculated on the basis of a captured image. Therefore,
the degree of third contribution can be said to be higher in
reliability than the conventional photographic conditions; for
example, the degree of contribution determined solely from the
illumination brightness of the flash, a distance to the subject,
and the like. In the present embodiment, an average brightness
value of the preview image is used as environment brightness
achieved before firing of strobe light. As long as environment
brightness acquired before firing of strobe can be estimated,
another value may also be used. For instance, a brightness value
used for determining whether or not strobe light is to be fired;
namely, an environment brightness value acquired before firing of
strobe light, such as a brightness value which is a requirement for
firing strobe light, may also be used.
[0078] When all of the first, second, and third degrees of
contribution are determined, the final degree of contribution FSC
is calculated from these three degrees of contribution (S20).
Specifically, the degree of final contribution FSC assumes a value
which is determined by adding together a product of the degree of
first contribution BSC and the degree of second contribution DW and
a product of the degree of first contribution BSC and the degree of
third contribution LW, and dividing the sum by two. Calculation of
the degree of final contribution FSC is represented by an equation
as follows:
FSC={(BSC.times.DW)+(BSC.times.LW)}/2
[0079] As mentioned above, the degree of final contribution FSC is
determined as an average value of the sums of products of the three
degrees of contribution, whereby a more reliable degree of
contribution can be obtained. Specifically, even when an error
component in any one of the three types of degrees of contribution
is large, the error component is diminished by the other two types
of degrees of contribution. Consequently, a more reliable, high
degree of contribution can be obtained. A formula for calculating
the degree of final contribution is an example and may be changed,
as appropriate. For instance, all of the first, second, and third
degrees of contribution are added together, and the sum may be
divided by three (FSC={(BSC+DW+LW)/3}).
[0080] As long as the degree of final contribution FSC can be
calculated, a WB gain is calculated in consideration of the degree
of final contribution FSC. Specifically, a captured image is first
divided into a plurality of blocks, and the types of light sources
of the respective blocks are identified. The degree of reliability
of the respective blocks is identified on the basis of the
brightness values of the respective blocks, and the like. An
additional value of reliability is calculated for each type of
light source. Summated values of the respective types of light
sources are taken as weighting coefficients of the respective types
of light sources. For instance, the result of determination of the
light source of each block is plotted as shown in FIG. 10. For the
sake of simplicity, the reliability of each block is taken as one.
In this case, the weighting coefficient of each type of light
source corresponds to the number of blocks achieved in connection
with each type of light source. Specifically, in the embodiment
shown in FIG. 10, the weighting coefficient of daylight (Dy) is
four; a weighting coefficient of tungsten light (Tn) is three; a
weighting coefficient of fluorescent light (F1) is three; and a
weighting coefficient of strobe light (St) is four.
[0081] When an image has been captured through strobe illuminated
photography, the weighting coefficient of strobe light among the
thus-calculated weighting coefficients is multiplied by the
previously-described degree of final contribution FSC.
Specifically, the weighting coefficient of strobe light is
corrected, as required, according to the degree of contribution of
strobe light. For instance, when the degree of final contribution
FSC is 0.8, the weighting coefficient of strobe light is correct to
a value determined by 40.8=3.2.
[0082] As long as the weighting coefficient of strobe light can be
corrected, a weighted average value between the weighting
coefficient of each type of the light source and the reference gain
value shown in FIG. 4 is calculated. The thus-calculated weighted
average value; namely, coordinates in the T space, are converted
into an RGB value, whereby a WB gain is obtained. In relation to
the thus-calculated WB gain, a correction component of strobe light
(a reference gain value Gs for strobe light) is adjusted, as
appropriate, according to the degree of contribution of strobe
light. Consequently, a preferable WB gain appropriate to the degree
of contribution of strobe light is obtained.
[0083] As has been described, according to the present embodiment,
the degree of contribution of strobe light is determined on the
basis of an actually-captured image, and a WB gain appropriate to
the degree of contribution is calculated. Consequently, a more
suitable WB gain can be obtained. Although in the present
embodiment all of the degrees of first, second, and third
contribution are calculated, a WB gain may be corrected by means of
solely the degree of first contribution or the degree of third
contribution. The WB gain is corrected by means of adding the
thus-obtained degree of final contribution FSC to the weighting
coefficient of strobe light. However, as a matter of course,
another correction method may also be used. For instance, the value
of a standard gain value Gs for strobe purpose may be changed
according to the degree of final contribution FSC.
PARTS LIST
[0084] 10 digital camera [0085] 12 aperture member [0086] 14 lens
[0087] 16 CCD [0088] 18 correlated double sampling (CDS) circuit
[0089] 20 amplifying circuit (AMP) [0090] 22 analog-to-digital
(A/D) converter [0091] 24 image memory [0092] 25 image processing
section [0093] 26 RGB separation section [0094] 28 WB processing
section [0095] 30 .gamma. correction section [0096] 32 color
correction section [0097] 34 LCD [0098] 36 timing generator (TG)
[0099] 38 memory controller [0100] 40 image memory [0101] 42
compression-and-expansion circuit [0102] 44 recording medium [0103]
46 strobe device [0104] 48 CPU [0105] 50 AE/AF strobe control
section [0106] 51 WB (White Balance) gain acquisition [0107] 52
degree of contribution computing section [0108] 54 memory [0109] 56
gain computing section [0110] 58 operation section [0111] S10 has
strobe light been fired [0112] S12 ordinary processing for
computing WB gain [0113] S14 estimate degree of contribution of
strobe light [0114] S16 estimate degree of contribution of strobe
light [0115] S18 estimate degree of contribution of strobe light
[0116] S20 compute degree of final contribution [0117] S22 compute
WB gain [0118] S23 divide captured image into blocks [0119] S24
specify brightest block [0120] S26 are there blocks of strobe color
[0121] S28 compute degree of tentative contribution SBW [0122] S30
degree of first contribution=1/2 [0123] S32 compute degree of
tentative contribution SBW [0124] S34 determine differences between
brightnesses [0125] S36 degree of first contribution BSC [0126] S38
difference between typical brightness value and predetermined
allowable range [0127] S40 compute mean brightness value [0128] S42
compare brightness values SBL [0129] S44 degree of first
contribution BSC=4/5 [0130] S46 degree of first contribution BSC=
[0131] S48 degree of first contribution BSC=1/5
* * * * *