U.S. patent application number 12/560212 was filed with the patent office on 2010-03-18 for automatic focusing apparatus and control method therefor.
This patent application is currently assigned to CANON KABUSHIKI KAISHA. Invention is credited to Masaaki Uenishi.
Application Number | 20100067891 12/560212 |
Document ID | / |
Family ID | 42007313 |
Filed Date | 2010-03-18 |
United States Patent
Application |
20100067891 |
Kind Code |
A1 |
Uenishi; Masaaki |
March 18, 2010 |
AUTOMATIC FOCUSING APPARATUS AND CONTROL METHOD THEREFOR
Abstract
An automatic focusing apparatus detects presence or absence of
change in a distance between an object and the automatic focusing
apparatus while operating in an operation mode to continuously
perform an adjustment of the position of a focus lens to focus on
the object, and stops a movement of the focus lens if a change in
the distance is not detected.
Inventors: |
Uenishi; Masaaki;
(Kawasaki-shi, JP) |
Correspondence
Address: |
CANON U.S.A. INC. INTELLECTUAL PROPERTY DIVISION
15975 ALTON PARKWAY
IRVINE
CA
92618-3731
US
|
Assignee: |
CANON KABUSHIKI KAISHA
Tokyo
JP
|
Family ID: |
42007313 |
Appl. No.: |
12/560212 |
Filed: |
September 15, 2009 |
Current U.S.
Class: |
396/104 |
Current CPC
Class: |
H04N 5/232123 20180801;
G03B 13/20 20130101; H04N 5/23218 20180801; G02B 7/36 20130101;
G03B 13/36 20130101; G02B 7/09 20130101; H04N 5/232941 20180801;
G02B 27/0093 20130101; H04N 5/23212 20130101; H04N 5/232933
20180801; G02B 7/38 20130101 |
Class at
Publication: |
396/104 |
International
Class: |
G03B 13/00 20060101
G03B013/00 |
Foreign Application Data
Date |
Code |
Application Number |
Sep 16, 2008 |
JP |
2008-237187 |
Claims
1. An automatic focusing apparatus comprising: an imaging unit
configured to capture an object image that is input via a focus
lens to output image data; a detection unit configured to detect a
focus signal that indicates a focusing state of the focus lens
based on the image data; a focus adjustment unit configured to
adjust a position of the focus lens based on the focus signal
detected by the detection unit; a control unit configured to cause
the focus adjustment unit to operate in an operation mode to
continuously perform an adjustment of the position of the focus
lens; and a distance change detection unit configured to detect,
when the focus adjustment unit is operating in the operation mode,
presence or absence of change in a distance between the object and
the automatic focusing apparatus, wherein the control unit stops
the adjustment of the position of the focus lens if a change in the
distance is not detected by the distance change detection unit.
2. The automatic focusing apparatus according to claim 1, wherein
the control unit resumes the adjustment of the position of the
focus lens if a change in the distance is detected by the distance
change detection unit after stopping the adjustment of the position
of the focus lens.
3. The automatic focusing apparatus according to claim 1, wherein
the distance change detection unit detects the presence or absence
of change in the distance between the object and the automatic
focusing apparatus based on an amount of change in a focus signal
continuously acquired while the focus adjustment unit is operating
in the operation mode.
4. The automatic focusing apparatus according to claim 1, further
comprising a luminance acquisition unit configured to acquire a
luminance value of the object based non the image data, wherein the
distance change detection unit detects the presence or absence of
change in the distance between the object and the automatic
focusing apparatus based on an amount of change in a luminance
value continuously acquired by the luminance acquisition unit while
the focus adjustment unit is operating in the operation mode.
5. The automatic focusing apparatus according to claim 1, further
comprising a first movement amount detection unit configured to
compare, in time series, the image data continuously acquired while
the focus adjustment unit is operating in the operation mode to
detect an amount of movement of the object, wherein the distance
change detection unit detects the presence or absence of change in
the distance between the object and the automatic focusing
apparatus based on the amount of movement of the object detected by
the first movement amount detection unit.
6. The automatic focusing apparatus according to claim 1, further
comprising a face detection unit configured to detect a face region
of a person included in the image data based on the image data,
wherein the distance change detection unit detects the presence or
absence of change in the distance between the object and the
automatic focusing apparatus based on a size change of the face
region continuously acquired by the face detection unit while the
focus adjustment unit is operating in the operation mode.
7. The automatic focusing apparatus according to claim 1, further
comprising a second movement amount detection unit configured to
detect an amount of movement of the automatic focusing apparatus,
wherein the distance change detection unit detects the presence or
absence of change in the distance between the object and the
automatic focusing apparatus based on the amount of movement of the
automatic focusing apparatus detected by the second movement amount
detection unit.
8. The automatic focusing apparatus according to claim 1, wherein
the distance change detection unit detects that there is no change
in the distance between the object and the automatic focusing
apparatus if a case where a position of the focus lens at which the
focus signal becomes maximal is included within a range set in
advance relative to a reference position determined based on a
latest adjustment result by the focus adjustment unit is repeated a
predetermined number of times.
9. A method for controlling an automatic focusing apparatus
including a focus adjustment unit configured to calculate a focus
evaluation value that indicates a contrast of a predetermined focus
detection area based on image data of an image of an object formed
and captured by a photographic optical system including a focus
lens, and to adjust a position of the focus lens so that the focus
evaluation value becomes maximal, and a control unit configured to
cause the focus adjustment unit to operate in an operation mode to
continuously perform an adjustment of the position of the focus
lens, the method comprising: detecting presence or absence of
change in a distance between the object and the automatic focusing
apparatus when the focus adjustment unit is operating in the
operation mode; and stopping the adjustment of the position of the
focus lens if a change in the distance is not detected.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates to an automatic focusing
apparatus, e.g., a camera, and a control method therefor.
[0003] 2. Description of the Related Art
[0004] Conventionally, an automatic focusing apparatus of an
auto-focusing (AF) system which focuses on an object by moving a
focus lens position according to a luminance signal obtained from
an image sensor, such as a charge-coupled device (CCD), has been
used in an electronic still camera or the like. In the automatic
focusing apparatus, a focus evaluation value indicating a contrast
within an AF area is calculated by integrating high-frequency
components of a signal in the AF area set within an image plane.
Then, a focus detection operation for acquiring a focus evaluation
value for each position of a focus lens is performed by shifting
the focus lens, to detect a position of the focus lens enabling the
highest focus evaluation value, which is regarded as an in-focus
point. Further, in an automatic focusing apparatus of the AF
system, by repeatedly performing the focus detection operation,
focusing can be also achieved on a moving object by tracking
it.
[0005] As a technology relating to an automatic focusing apparatus
which also enables focusing with respect to a moving object by
tracking it, Japanese Patent Application Laid-Open No. 2004-212556,
and Japanese Patent Application Laid-Open No. 2007-206433 are
known. Japanese Patent Application Laid-Open No. 2004-212556
discusses an imaging apparatus equipped with an automatic focusing
apparatus which causes an AF tracking to an object to be performed
by repeating a focus detection operation by a lens movement before
shooting. Further, Japanese Patent Application Laid-Open No.
2007-206433 discusses a technology for storing in advance in-focus
positions after having performed the focus detection operation for
each shooting, in a continuous shooting or the like, predicting an
in-focus position before a next shooting based on the previous
in-focus positions previously stored, thus determining a range for
a focus detection operation.
[0006] However, in the above-described conventional technology,
even in a case where a distance between an automatic focusing
apparatus and an object has not changed, e.g., the object comes to
rest, a focus detection operation is continuously performed so that
the focus lens is sequentially moved. For this reason, a focus
fluctuation always occurs, and a tracking ability to the object may
deteriorate. In particular, in an electronic viewfinder (EVF)
display using consecutive captured images, or the like, frames
which are out-of focus may be generated, and accordingly visual
quality may degrade. Further, the focus lens is sequentially moved,
thus leading to an increase in battery consumption.
SUMMARY OF THE INVENTION
[0007] The present invention is directed to an automatic focusing
apparatus capable of preventing tracking ability to an object from
deteriorating, even if a distance between the automatic focusing
apparatus and the object does not change, when continuously
performing an adjustment of position of a focus lens to make focus
on an object, and to a control method therefor.
[0008] According to an aspect of the present invention, an
automatic focusing apparatus includes an imaging unit configured to
capture an object image that is input via a focus lens to output
image data, a detection unit configured to detect a focus signal
that indicates a focusing state of the focus lens based on the
image data, a focus adjustment unit configured to adjust a position
of the focus lens based on the focus signal detected by the
detection unit, a control unit configured to cause the focus
adjustment unit to operate in an operation mode to continuously
perform an adjustment of the position of the focus lens, and a
distance change detection unit configured to detect, when the focus
adjustment unit is operating in the operation mode, presence or
absence of change in a distance between the object and the
automatic focusing apparatus, wherein the control unit stops the
adjustment of the position of the focus lens if a change in the
distance is not detected by the distance change detection unit.
[0009] Further features and aspects of the present invention will
become apparent from the following detailed description of
exemplary embodiments with reference to the attached drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] The accompanying drawings, which are incorporated in and
constitute a part of the specification, illustrate exemplary
embodiments, features, and aspects of the invention and, together
with the description, serve to explain the principles of the
invention.
[0011] FIG. 1 is a block diagram illustrating a configuration of an
imaging apparatus according to an exemplary embodiment of the
present invention.
[0012] FIG. 2 is a flowchart illustrating an operation of the
imaging apparatus.
[0013] FIG. 3 is a flowchart illustrating a subroutine of a
continuous AF operation.
[0014] FIG. 4 is a flowchart illustrating a subroutine of a servo
AF operation.
[0015] FIG. 5 is a flowchart illustrating a subroutine of a
hill-climbing AF operation.
[0016] FIG. 6 is a flowchart illustrating a subroutine of
determining whether object distance has changed.
[0017] FIG. 7 is a flowchart illustrating a subroutine of a normal
AF operation.
[0018] FIG. 8 is a flowchart illustrating a subroutine of a
continuous servo AF operation.
[0019] FIG. 9 is a flowchart illustrating a subroutine of a
determining predictability.
[0020] FIG. 10 is a flowchart illustrating a subroutine of
predicting an object position.
[0021] FIG. 11A is a conceptual view illustrating a calculation of
object position prediction at two points. FIG. 11B is a conceptual
view illustrating a calculation of object position prediction at
three points.
[0022] FIG. 12 is a flowchart illustrating a subroutine of
scanning.
[0023] FIG. 13 is a graph illustrating a relationship between a
focus evaluation value and a focus lens position.
[0024] FIG. 14 is a flowchart illustrating a subroutine of an
in-focus determination.
[0025] FIG. 15 is a flowchart illustrating a checking for a
monotonic decrease in an infinite distance end direction.
[0026] FIG. 16 is a flowchart illustrating a checking for a
monotonic decrease in a closest end direction.
[0027] FIG. 17 is a flowchart illustrating a subroutine of a
shooting operation.
DESCRIPTION OF THE EMBODIMENTS
[0028] Various exemplary embodiments, features, and aspects of the
invention will be described in detail below with reference to the
drawings.
[0029] FIG. 1 is a block diagram illustrating a configuration of an
imaging apparatus 1 according to an exemplary embodiment of the
present invention. As illustrated in FIG. 1, the imaging apparatus
1 is an electronic still camera, which captures an image by an
image sensor 108, the image being formed via a photographic optical
system including a photographic lens 101, a diaphragm and shutter
102, and a focus lens 104. Further, the imaging apparatus 1
includes an AF processing unit 105, which moves the focus lens 104
under the control of a control unit 115, and is configured to
perform focus adjustment by moving the focus lens 104 according to
image data captured by the image sensor 108.
[0030] The photographic lens 101 is an optical lens including a
zoom mechanism and so on. The diaphragm and shutter 102 controls a
light amount from an object according to control of an AE
processing unit 103 (AE: automatic exposure). The AE processing
unit 103 controls an aperture value and a shutter speed of the
diaphragm and shutter 102 under the control of the control unit
115. The focus lens 104 is moved along an optical axis by an
actuator (not illustrated), which moves in response to control of
the AF processing unit 105. Thereby, the focus lens 104 performs
focus adjustment of an image obtained in the image sensor 108. The
AF processing unit 105 controls a movement of the focus lens 104
under the control of the control unit 115 (the details will be
described below). Therefore, reflected light from the object enters
the photographic lens 101 and subsequently an amount of exposure is
adjusted via the diaphragm and shutter 102, and an image is formed
by the focus lens 104 and captured by the image sensor 108.
[0031] A flash unit 106 emits auxiliary light to the object in
response to the control of an EF processing unit 107 (EF:
pre-flash). The EF processing unit 107 controls a light emission of
the flash unit 106 under the control of the control unit 115. For
example, the EF processing unit 107 causes the flash unit 106 to
perform a preliminary light emission, before a main shooting by the
image sensor 108 performed under the control of the control unit
115, and detects an amount of reflected light from the object by a
sensor (not illustrated), and calculates an amount of light
emission during amain flash. Subsequently, the EF processing unit
107 causes the flash unit 106 to execute alight emission with
calculated amount of light emission, at the time of the main
shooting, thereby subjecting the object to a correct exposure.
[0032] The image sensor 108 outputs an image formed by the focus
lens 104 as image data converted into an electrical analog signal
by photoelectric conversion. More specifically, the image sensor
108 is typically a charge-coupled device (CCD) or a complementary
metal-oxide semiconductor (CMOS) sensor or the like. An
analog-to-digital (A/D) conversion unit 109 converts analog image
data, which is output from the image sensor 108, into digital image
data. Alternatively, the A/D conversion unit 109 may be configured
to include a correlated double sampling (CDS) circuit, which
eliminates an output noise of the image sensor 108, and a nonlinear
amplifier circuit operable before A/D conversion.
[0033] An image processing unit 110 performs various image
processes on digital image data output from the A/D conversion unit
109, and outputs processed digital image data. A white balance (WB)
processing unit 111 performs white balance processing on
image-processed digital image data output from the processing unit
110. A format conversion unit 112 converts a data format of the
image-processed digital image data output from the image processing
unit 110 into a predetermined image format such as a Joint
Photographic Experts Group (JPEG).
[0034] A dynamic random access memory (DRAM) 113 temporarily stores
image data converted into a predetermined image format by the
format conversion unit 112. Further, the DRAM 113 may be used as a
work area for the control unit 115 and a work area for
compression/decompression of the image data. An image recording
unit 114 includes a recording medium, such as a memory card, and an
interface of the recording medium (either of them not illustrated).
The image recording unit 114 records digital image data captured by
the image sensor 108, under the control of the control unit 115 and
temporarily stored in the DRAM 113, in the recording medium.
Alternatively, the recording medium of the image recording unit 114
may be attached to or detached from the imaging apparatus 1 via the
interface.
[0035] The control unit 115 conducts central control of operations
of respective units of the imaging apparatus 1. More specifically,
the control unit 115 includes a central processing unit (CPU), a
read-only memory (ROM), and so forth. The control unit 115
implements the above-described central control by causing the CPU
to read out program data stored in the ROM, to load the program
data onto the work area of the image recording unit 114, and to
execute in sequence the program data. For example, the control unit
115 controls system processing such as a shooting sequence by the
image sensor 108 according to an operation mode set by an operation
unit 118 and a shooting mode switch (SW) 119.
[0036] A video RAM (VRAM) 116 temporarily stores image data output
from the control unit 115 for use in a display of an operation
display unit 117. The operation display unit 117 is a display
device, such as a liquid crystal display (LCD) or the like, which
displays an image under the control of the control unit 115. The
operation display unit 117 performs a display for operational
support and a state display of the imaging apparatus 1, as well as
displays of a shooting image plane by an EVF during shooting
process and an AF area set in advance in the shooting image
plane.
[0037] The operation unit 118 includes buttons for receiving an
operation instruction from a user and outputting an operation
signal to the control unit 115, and a touch panel arranged on a
screen of the operation display unit 117, and others. More
specifically, the operation unit 118 includes a menu switch
operable to perform various types of settings, e.g., a setting of a
shooting function of the imaging apparatus 1 and a setting during
an image reproduction, a zoom lever operable to instruct a zooming
operation of the photographic lens 101, and the operation mode
changeover switch operable to switch a shooting mode and a
reproduction mode. The shooting mode SW 119 is a switch operable to
receive a changeover instruction of the shooting mode of the
imaging apparatus 1 from the user and to output it to the control
unit 115. For example, the shooting mode SW 119 receives from the
user the changeover instruction of ON or OFF of a face detection
mode for performing face detection from the captured image.
Further, the shooting mode SW 119 may receive a changeover
instruction of the AF mode from the user.
[0038] A main switch 120 is a switch operable to receive a power
ON/OFF instruction from the user and to output it to the control
unit 115. A first switch 121 is a switch operable to receive from
the user a start instruction of a shooting standby operation such
as starting the AF processing and AE processing in advance, and to
output the start instruction to the control unit 115. A second
switch 122 is a switch operable to receive from the user the start
instruction of shooting after the operation of the first switch 121
and to output the start instruction to the control unit 115.
Alternatively, the first switch 121 and the second switch 122 may
be configured such that the first switch 121 is turned ON by a half
press of a shutter button (not illustrated), and the second switch
122 is turned ON by a full press of the shutter button.
[0039] A face detection module 123 detects a face region of a
person from image-processed digital image data output from the
image processing unit 110, and outputs one or a plurality of pieces
of face information (position of face region, its size,
reliability, etc.) which have been detected to the control unit
115. Publicly known technologies can be applied to a method for
detecting a face of a person, and it has not a direct relationship
with the present invention, and thus detailed description will be
omitted.
[0040] In addition, publicly known face detection technologies
include a technique based on a learning which utilizes a neural
network, for example, a method for searching for areas which are
characteristic of shapes of eyes, nose, mouth, etc., using a
template matching from an image, and regarding it as a face if
similarity is high, and others. Further, besides, a technique for
detecting image feature quantity such as color of skin and shape of
eyes using a statistical analysis, and a number of other techniques
are discussed. Generally, accuracy of the face detection is
enhanced by combining a plurality of these techniques. A specific
example includes a method for face detection utilizing a wavelet
conversion and an image feature quantity, as discussed in Japanese
Patent Application Laid-Open No. 2002-251380.
[0041] A moving object detection unit 124 compares a plurality of
captured images which have been continuously captured by the image
sensor 108 with each other, and detects whether an object and
background are moving, and outputs information about the moving
object to the control unit 115. More specifically, the moving
object detection unit 124 compares two frames of the captured
images which are aligned side by side in time sequence, out of
image-processed digital image data output from the image processing
unit 110, and detects moving object information (amount of
movement, position, range) of the object and the background from
the difference information, and outputs it to the control unit
115.
[0042] An angular velocity sensor unit 125 detects a movement
(angular velocity) of the imaging apparatus 1 itself and outputs
movement information (amount of movement) thereof to the control
unit 115. More specifically, the angular velocity sensor unit 125
may be typically a gravity sensor or a gyro sensor, which detects a
position of sphere within a circular cavity and detects an
orientation of the imaging apparatus 1 relative to the vertical
direction.
[0043] Next, an operation of the imaging apparatus 1 performed
under the control of the control unit 115 will be described below
with reference to FIG. 2 to FIG. 17. FIG. 2 is a flowchart
illustrating an operation of the imaging apparatus 1. The control
unit 115 stores variables information for operation in the work
area of the DRAM 113, in a flowchart illustrated below, and
executes processing while reading out and updating the variables
information in each step. The variables information stored in the
work area of the DRAM 113 includes flag data and numerical data
such as calculated values and counter values.
[0044] The flag data includes an in-focus flag, a peak detection
flag, a distance change flag, a same direction movement flag, a
face detection flag, and others. The in-focus flag is flag data
that indicates a determined result in an in-focus determination. If
the in-focus flag is TRUE, it denotes that focus is achieved on an
object, and if FALSE, it indicates that focus is not achieved on
the object. The face detection flag is flag data that indicates
whether a face is detected in the face detection module 123. If the
face detection flag is TRUE, it indicates that a face is detected,
and if FALSE, it indicates that the face is not detected. A peak
detection flag is flag data that indicates that a peak where a
focus evaluation value becomes maximal in a hill-climbing AF
operation (focus detection operation) is detected. If the peak
detection flag is TRUE, it indicates that the peak is detected, and
if FALSE, it indicates that the peak is not detected. A distance
change flag is flag data that indicates that an object distance
between the imaging apparatus 1 and the object is changed. If the
distance change flag is TRUE, it indicates that the object distance
has changed, and if FALSE, it indicates that the object distance
has not changed. A same direction movement flag is flag data that
indicates whether a direction of a peak position relative to a scan
center position in a current focus detection operation is the same
as a direction of a peak position relative to a scan center
position in the previous focus detection operation. If the same
direction movement flag is TRUE, it indicates they are the same
directions, and if FALSE, it indicates that they are not the same
directions.
[0045] Further, numerical data includes a focus evaluation value
described above, an acquisition counter, an increase counter,
number of times of detected-face size change, number of times of
luminance value change, number of times of focus evaluation value
change, number of times of camera operation, number of times of
object operation, xcount value, and StCount value. The acquisition
counter is numerical data that indicates the number of times that
the current position of the focus lens 104 has been acquired. The
increase counter is numerical data that indicates that a focus
evaluation value acquired in the nearest preceding processing, in
the hill-climbing AF, is larger than a focus evaluation value
acquired in the preceding processing (the number of times). The
number of times of detected-face size change is numerical data that
indicates the number of times that a size of face detected by the
face detection module 123 in an image area of AF frame has changed.
The number of times of luminance value change is numerical data
that indicates the number of times that the luminance value has
changed in the image area of the AF frame. The number of times of
focus evaluation values change is numerical data that indicates the
number of times that the focus evaluation value has changed in the
image area of the AF frame. The number of times of camera operation
is numerical data that indicates the number of times that the
operation amount (amount of movement) of the imaging apparatus 1
has changed by an amount equal to or greater than a predetermined
value set in advance. The number of times of object operation
change is numerical data that indicates the number of times that an
operation amount of an object has changed by an amount equal to or
greater than a set in advance predetermined value. The xcount value
is numerical data that indicates the number of times that in-focus
determinations are not "o" determinations consecutively (number of
times of "x" determinations). The StCount value is numerical data
that indicates the number of times that differences between peak
positions and scan center positions become consecutively smaller
than a predetermined value.
[0046] As illustrated in FIG. 2, the imaging apparatus 1 starts
processing under the control of the control unit 115 by turning the
main switch 120 ON so as to turn the power on. If the processing is
started, then in step S201, the control unit 115 checks a remaining
capacity of the recording medium in the image recording unit 114.
If the remaining capacity is 0 (YES in step S201), then the
processing proceeds to step S202. If the remaining capacity is not
0 (NO in step S201), then the processing proceeds to step S203. In
step S201, in advance of a detection of the remaining capacity, the
control unit 115 may detect whether the recording medium exists in
the image recording unit 114. If the recording medium is not
connected thereto, the processing may proceed to step S201.
[0047] If the remaining capacity of the storage medium of the image
recording unit 114 is 0, the control unit 115 displays a warning
that the remaining capacity of the image recording unit 114 is 0 to
the operation display unit 117 in step S202, and then the
processing returns to step S201. Alternatively, in step S202, the
control unit 115 may output a warning sound from an audio output
unit (not illustrated) constituted by an amplifier and speaker, or
may perform the both of warning display by the operation display
unit 117 and an output of the warning sound by the audio output
unit.
[0048] In step S203, the control unit 115 checks whether the AF
mode is set to a continuous AF mode or a single AF mode. If the AF
mode is set to the continuous AF mode (YES in step S203), the
processing proceeds to step S204. If the AF mode is set to the
single AF mode (NO in step S203), the processing proceeds to step
S207. The above-described AF mode is set in advance according to an
instruction from a user via the shooting mode SW 119. The single AF
mode is an AF mode in which a focus detection operation is executed
one time immediately before the shooting operation so that focus is
achieved on an object. The continuous AF mode is an AF mode in
which the focus detection operation is repeatedly executed before
the shooting operation to achieve good focus on the object. The
continuous AF mode includes a servo AF mode, which is operable
prioritizing the focus detection operation rather than a visual
quality of the EVF display. In other words, the continuous AF mode
or the servo AF mode is an operation mode in which the adjustment
of position of the focus lens is continuously performed.
[0049] In step S204, the control unit 115 checks whether, in an
instruction from a user via the operation unit 118, the visual
quality of the EVF display is prioritized or an AF tracking which
repeatedly executes the focus detection operation is prioritized.
If the visual quality of the EVF display is prioritized (YES in
step S204), the processing proceeds to step S205. If the AF
tracking is prioritized (NO in step S204), the processing proceeds
to step S206.
[0050] In step S205, the control unit 115 performs the continuous
AF according to the flowchart of FIG. 3 described below, and then
the processing proceeds to step S207. In step S206, the control
unit 115 performs the servo AF according to the flowchart of FIG. 4
described below, and then the processing proceeds to step S207.
[0051] In step S207, the control unit 115 checks a state of the
first switch 121. If the first switch is ON (YES in step S207), the
processing proceeds to step S208. If the first switch is OFF (NO in
step S207), the processing proceeds to step S201. In step S208, the
control unit 115 performs the AE processing from an output of the
image processing unit 110 by the AE processing unit 103, and then
the processing proceeds to step S209. In step S209, the control
unit 115 checks a state of the in-focus flag. If the in-focus flag
is TRUE (YES in step S209), the processing proceeds to step S211.
If the in-focus flag is FALSE (NO in step S209), the processing
proceeds to step S210.
[0052] In step S210, the control unit 115 performs a normal AF
operation according to the flowchart of FIG. 7 described below, and
then the processing proceeds to step S211. In step S211, the
control unit 115 checks whether the AF mode is set to the servo AF
mode. If the AF mode is set to the servo AF mode (YES in step
S211), the processing proceeds to step S212. If the AF mode is not
set to the servo AF mode (NO in step S211), the processing proceeds
to step 213. In step S212, the control unit 115 performs the servo
AF according to the flowchart of FIG. 4 described below, and then
the processing proceeds to step S213.
[0053] In step S213, the control unit 115 checks a state of the
first switch 121. If the first switch 121 is ON (YES in step S213),
the processing proceeds to step S214. If the first switch 121 is
OFF (NO in step S213), the processing proceeds to step S201. In
step S214, the control unit 115 checks a state of the second switch
122. If the second switch 122 is ON (YES in step S214), the
processing proceeds to step S215. If the second switch 122 is OFF
(NO in step S214), the processing proceeds to step S211. In step
S215, the control unit 115 performs a shooting operation according
to the flowchart of FIG. 17 described below, and then the
processing proceeds to step S201.
[0054] Through the above-described processing, in the imaging
apparatus 1, the processing from step S201 to step S207 will be
performed in a loop, until the power is turned ON and the first
switch 121 is turned ON. Further, in the imaging apparatus 1, when
the first switch 121 is turned ON, the processing from step S208 to
step S213 will be performed, and in a state that the first switch
121 remains to be ON and the second switch 122 is turned OFF, the
processing from step S211 to step S213 will be performed in a loop.
Then, when the second switch 122 is turned ON, in a state that the
first switch 121 is turned ON, the shooting process will be
performed.
[0055] Next, a subroutine of the continuous AF in step S205 in the
flowchart of FIG. 2 will be described below with reference to the
flowchart of FIG. 3. As illustrated in FIG. 3, when the continuous
AF is started, then in step S301, the control unit 115 checks
whether face detection is available in the face detection module
123. If the face detection is available (YES in step S301), the
processing proceeds to step S302. If the face detection is not
available (NO in step S301), the processing proceeds to step
S304.
[0056] In steep S302, the control unit 115 acquires face
information such as a face position and a face size detected by the
face detection module 123, and then the processing proceeds to step
S303. In step S303, the control unit 115 sets a face detection
flag, which indicates that a face has been detected, to TRUE, and
then the processing proceeds to step S304.
[0057] In step S304, the control unit 115 checks a state of the
face detection flag. If the face detection flag is TRUE (YES in
step S304), the processing proceeds to step S305. If the face
detection flag is FALSE (NO in step S304), the processing proceeds
to step S306.
[0058] In step S305, the control unit 115 sets an AF frame (focus
detection area) to a latest face detection position detected by the
face detection module 123, and then the processing proceeds to step
S307. In this process, a size of the AF frame when a face is
detected, may be set to a predetermined size set in advance in a
ROM or the like, or may be set to a size corresponding to a face
size detected by the face detection module 123. In step S306, the
control unit 115 sets the AF frame to a predetermined position set
in advance such as a central area, and then the processing proceeds
to step S307. In step S307, the control unit 115 acquires a focus
evaluation value (contrast value) and a luminance value in an image
area within the AF frame set in step S305 or S306, and then the
processing proceeds to step S308.
[0059] In step S308, the control unit 115 checks a state of the
peak detection flag, which indicates that a peak has been detected
in a hill-climbing AF operation in step S309 described below. If
the peak detection flag is TRUE (YES in step S308), the processing
proceeds to step S310. If the peak detection flag is FALSE (NO in
step S308), the processing proceeds to step S309. In step S309, the
control unit 115 performs the hill-climbing AF operation according
to the flowchart of FIG. 5 described below. Then, a subroutine of
the continuous AF ends, and then the processing proceeds to step
S207.
[0060] In step S310, the control unit 115 determines whether an
object distance has changed according to the flowchart of FIG. 6
described below, and then the processing proceeds to step S311. In
step S311, the control unit 115 checks a state of the distance
change flag, which indicates the object distance has changed. If
the distance change flag is TRUE (YES in step S311), the processing
proceeds to step S312. If the distance change flag is FALSE (NO in
step S311), the processing proceeds to step S313.
[0061] In step S312, the control unit 115 sets the peak detection
flag and the distance change flag to FALSE. After that, the control
unit 115 resets a maximum value of a focus evaluation value, a peak
position, used in the subroutine of the hill-climbing AF operation
in step S309, and the increase counter, which indicates an increase
of the focus evaluation value, and then the processing proceeds to
step S313. In step S313, the control unit 115 causes the focus lens
to remain stopped, and then the processing proceeds to step
S207.
[0062] Next, a subroutine of the servo AF operation in steps S206
and S212 in the flowchart of FIG. 2 will be described below with
reference to the flowchart of FIG. 4. As illustrated in FIG. 4,
when the servo AF operation is started, the control unit 115 checks
whether face detection is available in the face detection module
123 in step S401. If the face detection is available (YES in step
S401), the processing proceeds to step S402. If the face detection
is not available (NO in step S401), the processing proceeds to step
S404.
[0063] In step S402, the control unit 115 acquires face information
such as face position/face size detected by the face detection
module 123, and then the processing proceeds to step S403. In step
S403, the control unit 115 sets the face detection flag, which
indicates that the face is being detected, to TRUE, and then the
processing proceeds to step S404.
[0064] In step S404, the control unit 115 checks a state of the
face detection flag. If the face detection flag is TRUE (YES in
step S404), the processing proceeds to step S405. If the face
detection flag is FALSE (NO in step S404), the processing proceeds
to step S406.
[0065] In step S405, the control unit 115 sets the AF frame to a
latest face detection position detected by the face detection
module 123, and then the processing proceeds to step S407.
Alternatively, the control unit 115 may set a size of the AF frame
when the face is being detected to a predetermined size set in
advance, or may set it to a size corresponding to a detected-face
size. In step S406, the control unit 115 sets the AF frame to a
predetermined position set in advance such as a central area, and
then the processing proceeds to step S407. In step S407, the
control unit 115 acquires a focus evaluation value and a luminance
value in an image area within the AF frame, which has been set in
step S405 or S406, and then the processing proceeds to step
S408.
[0066] In step S408, the control unit 115 checks a state of the
peak detection flag, which indicates that a peak is detected in the
hill-climbing AF operation of S409 described below. If the peak
detection flag is TRUE (YES in step S408), the processing proceeds
to step S410. If the peak detection flag is FALSE (NO in step
S408), the processing proceeds to step S409. In step S409, the
control unit 115 performs the hill-climbing AF operation according
to the flowchart of FIG. 5 described below. Then, a subroutine of
the servo AF operation ends. Then, the processing proceeds to step
S207 or S213.
[0067] In step S410, the control unit 115 checks a state of the
distance change flag, which indicates that the object distance has
changed. If the distance change flag is TRUE (YES in step S410),
the processing proceeds to step S412. If the distance change flag
is FALSE (NO in step S410), the processing proceeds to step S411.
In step S411, the control unit 15 checks whether the in-focus flag
is TRUE. If the in-focus flag is TRUE (YES in step S411), the
processing proceeds to step S413. If the in-focus flag is FALSE (NO
in step S411), the processing proceeds to step S412.
[0068] In step S412, the control unit 115 performs a continuous
servo AF operation according to the flowchart of FIG. 8 described
below. Then, the subroutine of the servo AF operation ends. Then,
the processing proceeds to step S207 or S213. In step S413, the
control unit 115 determines whether the object distance has changed
according to the flowchart of FIG. 6 described below. Then, a
subroutine of the servo AF operation ends. Then, the processing
proceeds to step S207 or S213.
[0069] Next, a subroutine of the hill-climbing AF operation in step
S309 in the flowchart of FIG. 3 and step S409 in the flowchart of
FIG. 4 will be described below with reference to the flowchart of
FIG. 5. As illustrated in FIG. 5, when the hill-climbing AF
operation is started, in step S501, the control unit 115 acquires a
current position of the focus lens 104, and then the processing
proceeds to step S502.
[0070] In step S502, the control unit 115 acquires a focus
evaluation value and a luminance value in the image area within the
AF frame which has been set, and increments the acquisition counter
for counting acquisitions of current positions of the focus lens
104, and then the processing proceeds to step S503. The acquisition
counter is assumed to be set in advance to 0 (or NULL value) in an
initialization operation (not illustrated).
[0071] In step S503, the control unit 115 checks whether the value
of the acquisition counter is 1. If the value of the acquisition
counter is 1 (YES in step S503), the processing proceeds to step
S506. If the value of the acquisition counter is not 1 (NO in step
S503), the processing proceeds to step S504.
[0072] In step S504, the control unit 115 checks whether a "current
focus evaluation value" acquired in nearest preceding processing is
greater than a "previous focus evaluation value" acquired in the
preceding processing. If the "current focus evaluation value" is
greater than the "previous focus evaluation value" (YES in step
S504), the processing proceeds to step S505. If the "current focus
evaluation value" is equal to or smaller than the "previous focus
evaluation value" (NO in step S504), the processing proceeds to
step S512.
[0073] In step S505, the control unit 115 increments by 1 the
increase counter, which indicates the "current focus evaluation
value" is greater than the "previous focus evaluation value", and
then the processing proceeds to step S505. The increase counter is
assumed to be set in advance to 0 (or NULL value) in the
initialization operation described above.
[0074] In step S506, the control unit 115 stores the current focus
evaluation value in an arithmetic memory (not illustrated)
incorporated in the control unit 115 as a maximum value (peak
evaluation value) of focus evaluation values, and then the
processing proceeds to step S507. In step S507, the control unit
115 stores a current position of the focus lens 104 in the
arithmetic memory incorporated in the control unit 115 as a peak
position of the focus evaluation value, and then the processing
proceeds to step S508. In step S508, the control unit 115 stores a
current focus evaluation value in the arithmetic memory
incorporated in the control unit 115 as the previous focus
evaluation value, and then the processing proceeds to step
S509.
[0075] In step S509, the control unit 115 checks whether the
current position of the focus lens 104 is at an end of a movement
range set in advance. If the focus lens is located at the end of
the movement range (YES in step S509), the processing proceeds to
step S510. If the focus lens is not located at the end of the
movement range (NO in step S509), the processing proceeds to step
S511. Note that the movement range is representative of the
movement range of the focus lens 104 set by processing described
below, and a movable range of the focus lens 104 is assumed to have
been set in advance in a standard state. A scanning operation such
as the hill-climbing AF operation is performed by moving the focus
lens 104 within the movement range previously set.
[0076] In step S510, the control unit 115 reverses a moving
direction of the focus lens 104, and then the processing proceeds
to step S511. In step S511, the control unit 115 moves the focus
lens 104 by a predetermined amount set in advance. Then, a
subroutine of the hill-climbing AF operation ends.
[0077] In step S512, the control unit 115 reads out a peak
evaluation value stored in the arithmetic memory, and checks
whether "peak evaluation value--current focus evaluation value" is
greater than a predetermined amount set in advance (threshold
value). If the difference is greater than the predetermined amount
(YES in step S512), the processing proceeds to step S513. If the
difference is equal to or less than the predetermined amount (NO in
step S512), the processing proceeds to step S508. In this process,
if the "peak evaluation value--current focus evaluation value" is
greater than the predetermined amount, and the current focus
evaluation value is decreased by the predetermined amount from the
peak evaluation value, the peak evaluation value is regarded as a
focus evaluation value when focusing on the object. In other words,
the focus lens 104 is moved within the movement range, and an
inflection point where the focus evaluation value turns from an
increase to a decrease is regarded as a focus evaluation value when
focusing on the object.
[0078] In step S513, the control unit 115 checks whether the
increase counter is greater than 0. If the increase counter is
greater than 0 (YES in step S513), the processing proceeds to step
S514. If the increase counter is equal to or smaller than 0 (NO in
step S513), the processing proceeds to step S508.
[0079] In step S514, the control unit 115 moves the focus lens 104
to a peak position where a focus evaluation value stored in S507
becomes a maximum value, and then the processing proceeds to step
S515. In step S515, the control unit 11 sets the peak detection
flag to TRUE, and then the processing proceeds to step S516. In
step S516, the control unit 115 sets the acquisition counter to 0,
and then the processing proceeds to step S207.
[0080] Next, a subroutine of determining whether object distance
has changed in step S310 in the flowchart of FIG. 3 and step S413
in the flowchart of FIG. 4 will be described below with reference
to the flowchart of FIG. 6. As illustrated in FIG. 6, when a
subroutine of determining whether the object distance has changed
is started, the control unit 115 checks whether a face detection is
available in the face detection module 123 in step S601. If the
face detection is available (YES in step S601), the processing
proceeds to step S602. If the face detection is not available (NO
in step S601), the processing proceeds to step S606.
[0081] In step S602, the control unit 115 checks whether a size of
face detected in a current processing has changed by a
predetermined percentage set in advance or more with respect to a
size of face detected in a previous processing. In other words, in
step S602, in the operation mode in which the adjustment of a
position of the focus lens is continuously performed, the control
unit 115 detects presence or absence of change in a distance from
the object depending on whether a size of face region of a person
continuously acquired has changed by a predetermined percentage or
more. If the size of detected face has changed by the predetermined
percentage or more (YES in step S602), the processing proceeds to
step S603. If the size of detected-face has not changed by the
predetermined percentage or more (NO in step S602), the processing
proceeds to step S606. In step S603, the control unit 115
increments the number of times of detected-face size change, and
then the processing proceeds to step S604. In step S604, the
control unit 115 checks whether the number of times of face size
change is equal to or greater than a threshold value set in
advance. If the number of times of face size change is equal to or
greater than the threshold value (YES in step S604), the processing
proceeds to step S605. If the number of times of face size change
is less than the threshold value (NO in step S604), the processing
proceeds to step S606. In step S605, the control unit 115 sets the
in-focus flag to FALSE and sets the distance change flag to TRUE.
Then, a subroutine of determining whether the object distance has
changed ends.
[0082] In step S606, the control unit 115 checks whether a
luminance value acquired in the current processing has changed by a
predetermined value set in advance or more with respect to a
luminance value acquired in the previous processing. In other
words, in step S606, the presence or absence of change in a
distance from the object is detected, depending on whether a change
amount of continuously acquired luminance values has changed by the
predetermined value or more, in the operation mode in which the
adjustment of position of the focus lens is continuously performed.
If the luminance value has changed by the predetermined value or
more (YES in step S606), the processing proceeds to step S607. If
the luminance value has not changed by the predetermined value or
more (NO in step S606), the processing proceeds to step S609. In
step S607, the control unit 115 increments the number of times of
luminance value change, and then the processing proceeds to step
S608. In step S608, the control unit 115 checks whether the number
of times of the luminance value change is equal to or greater than
a threshold value set in advance. If the number of times is equal
to or greater than the threshold value (YES in step S608), the
processing proceeds to step S605. If the number of times is less
than the threshold value (NO in step S608), the processing proceeds
to step S609.
[0083] In step S609, the control unit 115 checks whether a focus
evaluation value acquired in the current processing has changed by
a predetermined value set in advance or more, with respect to a
focus evaluation value acquired in the previous processing. In
other words, in step S609, the presence or absence of change in a
distance from the object is detected depending on whether a change
amount of the focus evaluation value continuously acquired, in the
operation mode in which the adjustment of a position of the focus
lens is continuously performed, has changed by the predetermined
value or more. If the focus evaluation value has changed by the
predetermined value or more (YES in step S609), the processing
proceeds to step S610. If the focus evaluation value has not
changed by the predetermined value or more (NO in step S609), the
processing proceeds to step S612. In step S610, the control unit
115 increments the number of times of focus evaluation value
change, and then the processing proceeds to step S611. In step
S611, the control unit 115 checks whether the number of times of
focus evaluation value change is equal to or greater than a
threshold value set in advance. If the number of times is equal to
or greater than the threshold value (YES in step S611), the
processing proceeds to step S605. If the number of times is not
equal to or greater than the threshold value (NO in step S611), the
processing proceeds to step S612.
[0084] The control unit 115 checks whether a camera operation
amount of the imaging apparatus 1 detected by the angular velocity
sensor unit 125 has changed by a predetermined value set in advance
or more. In other words, in step S612, the presence or absence of
change in a distance from the object is detected according to an
operation amount of the imaging apparatus 1, in the operation mode
in which the adjustment of a position of the focus lens is
continuously performed. If the camera operation amount has changed
by the predetermined value or more (YES in step S612), the
processing proceeds to step S613. If the camera operation amount
has not changed by the predetermined value or more (NO in step
S612), the processing proceeds to step S615. In step S613, the
control unit 115 increments the number of times of the camera
operation, and then the processing proceeds to step S614. In step
S614, the control unit 115 checks whether the number of times of
the camera operation is equal to or greater than a threshold value
set in advance. If the number of times is equal to or greater than
the threshold value (YES in step S614), the processing proceeds to
step S605. If the number of times is less than the threshold value
(NO in step S614), the processing proceeds to step S615.
[0085] In step S615, the control unit 115 checks whether an
operation amount of an object detected by the moving object
detection unit 124 is equal to or greater than a predetermined
value set in advance. In other words, in step S615, the presence or
absence of change in a distance from the object is detected
according to an operation amount of the object, in the operation
mode in which the adjustment of a position of the focus lens is
continuously performed. If the operation amount of the object is
equal to or greater than the predetermined value (YES in step
S615), the processing proceeds to step S616. If the operation
amount of the object is not equal to or greater than the
predetermined value (NO in step S615), the processing proceeds to
step S618. In step S616, the control unit 115 increments the number
of times of the object operation, and then the processing proceeds
to step S617. In step S617, the control unit 115 checks whether the
number of times of the object operation is equal to or greater than
a threshold value set in advance. If the number of times is equal
to or greater than the threshold value (YES in step S617), the
processing proceeds to step S605. If the number of times is less
than the threshold value (NO in step S617), the processing proceeds
to step S618.
[0086] In step S618, the control unit 115 checks whether any
evaluation value of a face detection size/a luminance value/a focus
evaluation value is in an unchanged state, and a camera operation
amount and an object operation amount are not equal to or greater
than a predetermined value. If any evaluation value is in an
unchanged state, and any operation amount is not equal to or
greater than the predetermined value (YES in step S618), the
processing proceeds to step S619. Further, if any evaluation value
is in a changed state, or, any operation amount is equal to or
greater than the predetermined value (NO in step S618), then the
subroutine of determining whether the object distance has changed
ends. In step S619, the control unit 115 sets all of the number of
times of face size change/the number of times of luminance value
change/the number of times of focus evaluation value change, the
number of times of camera operation, and the number of times of
object operation to 0 (or NULL value). Then, the subroutine of
determining whether the object distance has changed ends.
[0087] As described above, the control unit 115 performs the
subroutine of determining whether the object distance has changed,
which detects the presence or absence of a change in the distance
between the object and the imaging apparatus 1, even in the
continuous AF mode or the servo AF mode. Consequently, in the
imaging apparatus 1, the movement of the focus lens can be
controlled according to the distance change flag, which represents
a detection result that the presence or absence of change in the
distance between the object and the imaging apparatus 1 has been
detected, in the operation mode in which the adjustment of a
position of the focus lens is continuously performed. For example,
when a distance between the object and the imaging apparatus 1 has
changed, the movement of the focus lens, which has been stopped,
can be resumed by setting the distance change flag to TRUE.
[0088] Next, a subroutine of the normal AF operation in S210 in the
flowchart of FIG. 2 will be described below with reference to the
flowchart of FIG. 7. As illustrated in FIG. 7, when the normal AF
operation is started, then the control unit 115 checks whether a
face detection is available in the face detection module 123 in
step S701. If the face detection is available (YES in step S701),
the processing proceeds to step S702. If the face detection is not
available (NO in step S701), the processing proceeds to step
S704.
[0089] In step S702, the control unit 115 acquires face information
such as face position/face size detected by the face detection
module 123, and then the processing proceeds to step S703. In step
S703, the control unit 115 sets the face detection flag, which
indicates that the face detection is available, to TRUE, and then
the processing proceeds to step S704.
[0090] In step S704, the control unit 115 checks a state of the
face detection flag. If the face detection flag is TRUE (YES in
step S704), the processing proceeds to step S705. If the face
detection flag is FALSE (NO in step S704), the processing proceeds
to step S706.
[0091] In step S705, the control unit 115 sets the AF frame to a
latest face detection position, and then the processing proceeds to
step S707. Alternatively, a size of the AF frame when the face is
being detected may be set to a predetermined size set in advance,
or may be set to a size corresponding to the detected face size. In
step S706, the control unit 115 sets the AF frame to a
predetermined position set in advance such as a central area, and
then the processing proceeds to step S707.
[0092] In step S707, the control unit 115 checks whether the AF
mode set by the shooting mode SW 119 is the continuous AF, or, the
single AF mode. If the AF mode is set to the continuous AF mode
(YES in step S707), the processing proceeds to step S708. If the AF
mode is set to the single AF mode (NO in step S707), the processing
proceeds to step S710.
[0093] In step S708, the control unit 115 checks whether the peak
detection flag is TRUE. If the peak detection flag is TRUE (YES in
step S708), the processing proceeds to step S711. If the peak
detection flag is FALSE (NO in step S708), the processing proceeds
to step S710. In step S710, the control unit 115 sets a movement
range to the whole range (first range) of a movable range of the
focus lens 104, and then the processing proceeds to step S712. In
step S711, the control unit 115 sets a predetermined range set in
advance (second range) centering on a current position of the focus
lens 104 as a movement range, and then the processing proceeds to
step S712.
[0094] In step S711, since a peak evaluation value at which an
object is at focus has been detected, a second range, narrowed down
to narrower than the first range, is set as a movement range
centering on a lens position of the focus lens 104 where the peak
evaluation value is attained. Therefore, in the imaging apparatus
1, a focus detection operation in the normal AF operation can be
efficiently performed by the setting of the movement range in step
S711.
[0095] In step S712, the control unit 115 performs the focus
detection operation according to the flowchart of FIG. 12 described
below, and then the processing proceeds to step S713. In step S713,
the control unit 115 performs the in-focus determination according
to the flowchart of FIG. 13 described below, and then the
processing proceeds to step S714.
[0096] In step S714, the control unit 115 checks whether a result
of the in-focus determination in step S713 (the details will be
described below) is determined as "o". If it is determined as "o"
(YES in step S714), the processing proceeds to step S715. If it is
determined as "x" (NO in step S714), the processing proceeds to
step S717.
[0097] In step S715, the control unit 115 moves the focus lens 104
to a peak position calculated in the scanning in step S712, and
then the processing proceeds to step S716. In step S716, the
control unit 115 sets the peak detection flag and the in-focus flag
to TRUE, and sets the distance change flag to FALSE. Then, the
subroutine of the normal AF operation ends.
[0098] In step S717, the control unit 115 moves the focus lens 104
to a position set in advance (fixed point), and then the processing
proceeds to step S718. In the process, the fixed point is set to a
distance where probability that an object exists is high. If a face
has been detected, the fixed point may be set to a calculated
distance by estimating a distance of a person from a face size. In
step S718, control unit 115 sets the peak detection flag and the
distance change flag to FALSE. Then, the subroutine of the normal
AF operation ends.
[0099] Next, a subroutine of the continuous servo AF operation in
step S412 in the flowchart of FIG. 4 will be described below with
reference to the flowchart of FIG. 8. As illustrated in FIG. 8, in
step S801, the control unit 115 acquires a current time from a real
time clock (RTC) unit (not illustrated), and calculates a time
taken for a next scan (scan in step S810 described below). Next,
the control unit 115 calculates a time (predicted time) when a
position of the focus lens 104 is located at a center of the
movement range, in the next scan, to determine PreTime, and then
the processing proceeds to step S802. In step S802, the control
unit 115 performs predictability determination according to the
flowchart of FIG. 9 described below, and then the processing
proceeds to step S803.
[0100] In step S803, the control unit 115 checks whether a result
of the predictability determination in the predictability
determination in step S802 is predictable. If the result is
predictable (YES in step S803), the processing proceeds to step
S804. If the result is not predictable (NO in step S803), the
processing proceeds to step S805.
[0101] In step S804, the control unit 115 predicts an object
position according to the flowchart of FIG. 10 described below, and
then the processing proceeds to step S807. In step S805, the
control unit 115 clears previous data for prediction of a moving
object as will be described below, i.e, ScanTime [0] to ScanTime
[i-1] and HokanPeak [0] to HokanPeak [i-1]. Furthermore, the
control unit 115 sets a variable i to 0, and then the processing
proceeds to step S806. The variable i indicates the number of times
that it has been consecutively determined to be predictable. In
step S806, the control unit 115 sets a current position of the
focus lens 104 to a scan center position, and then the processing
proceeds to step S807.
[0102] In step S807, the control unit 115 checks whether the
in-focus flag is TRUE. If the in-focus flag is TRUE (YES in step
S807), the processing proceeds to step S808. If the in-focus flag
is FALSE (NO in step S807), the processing proceeds to step S809.
In step S808, the control unit 115 sets a movement range to a
predetermined range set in advance (third range), and then the
processing proceeds to step S810. In step S809, the control unit
115 sets the movement range to a range (fourth range) wider than
the third range previously set in step S808, the processing
proceeds to step S810. In step S809, it is apparent from the
in-focus flag that a peak evaluation value at which an object is at
the focus is not detected. Consequently, a scanning operation is
performed by setting the movement range to the fourth range wider
than the third range, causing focusing to the object to be
unerringly performed.
[0103] In step S810, the control unit 115 performs scanning
according to the flowchart of FIG. 12 described below, and then the
processing proceeds to step S811. In step S811, the control unit
115 performs the in-focus determination according to the flowchart
of FIG. 13 described below, and then the processing proceeds to
step S812.
[0104] In step S812, the control unit 115 checks whether a result
of the in-focus determination performed in step S811 is determined
as "o". If the result is determined as "o" (YES in step S812), the
processing proceeds to step S813. If the result is determined as
"x" (NO in step S812), the processing proceeds to step S825.
[0105] In step S813, the control unit 115 sets the in-focus flag to
TRUE, and then the processing proceeds to step S814. In step S814,
the control unit 115 sets xcount to 0, and then the processing
proceeds to step S815. The xcount indicates the number of times
that the in-focus determination has not consecutively been
determined as "o" (the number of times that it has been determined
as "x").
[0106] In step S815, the control unit 115 checks whether a
difference between a scan result (peak position) in step S810 and a
scan center position is smaller than a predetermined value set in
advance. If the difference is smaller than the predetermined value
(YES in step S815), the processing proceeds to step S816. If the
difference is not smaller than the predetermined value (NO in step
S815), the processing proceeds to step S819.
[0107] In step S816, the control unit 115 increments StCount that
indicates the number of times a difference between the peak
position in step S810 and the scan center position has been
consecutively smaller than a predetermined value, and then the
processing proceeds to step S817. In step S817, the control unit
115 checks whether the StCount is equal to or greater than a
threshold value set in advance. If the StCount is equal to or
greater than the threshold value (YES in step S817), the processing
proceeds to step S818. If the StCount is less than the threshold
value (NO in step S817), the processing proceeds to step S820. In
other words, the control unit 115 determines whether a focus lens
position at which a focus evaluation value becomes maximal is
included within a range set in advance, relative to a reference
position (scan center position) determined based on an adjustment
result of the focus lens 104 by the continuous servo AF operation.
Then, the control unit 115 determines whether a state that the
focus lens position at which the focus evaluation value becomes
maximal is included within the range set in advance, is repeated by
the number of times set in advance, and detects the presence or
absence of a distance change.
[0108] In step S818, the control unit 115, upon determining that
the distance change of the object has stopped, sets the distance
change flag to FALSE. In step S818a, the control unit 115 stops a
movement of the focus lens 104. Then, the subroutine of the
continuous servo AF operation ends. Consequently, in the imaging
apparatus 1, if the object distance does not change even in the
servo AF, stopping the focus lens can prevent a scan in the servo
AF from being uselessly repeated.
[0109] In step S819, the control unit 115 clears the StCount to 0,
and then the processing proceeds to step S820. In step S820, the
control unit 115 checks whether a direction of a current peak
position relative to a current scan center position in step S810 is
the same as that of a previous peak position relative to a previous
scan center position. If the both directions are the same (YES in
step S820), the processing proceeds to step S821. If the both
directions are not the same (NO in step S820), the processing
proceeds to step S822.
[0110] In step S821, the control unit 115 sets the same direction
movement flag to TRUE, and then the processing proceeds to step
S823. In step S822, the control unit 115 sets the same direction
movement flag to FALSE, and then the processing proceeds to step
S823.
[0111] In step S823, the control unit 115 assumes a time when the
position of the focus lens 104 in the current scan is located at a
center of a movement range to be ScanTime[i], and a peak position
in the current scan to be HokanPeak[i], and then the processing
proceeds to step S824. In step S824, the control unit 115
increments i. Then, the subroutine of the continuous servo AF
operation ends.
[0112] In step S825, the control unit 115 sets the in-focus flag to
FALSE, and then the processing proceeds to step S826. In step S826,
the control unit 115 increments the xCount, and then the processing
proceeds to step S827.
[0113] In step S827, the control unit 115 checks whether the xCount
is greater than a predetermined value set in advance. If the xCount
is greater than the predetermined value (YES in step S827), the
processing proceeds to step S828. If the xCount is not greater than
the predetermined value (NO in step S827), then the subroutine of
the continuous servo AF operation ends. In step S828, the control
unit 115 sets the peak detection flag and the distance change flag
to FALSE. Then, the subroutine of the continuous servo AF operation
ends.
[0114] Next, a subroutine of the predictability determination in
step S802 in the flowchart of FIG. 8 will be described below with
reference to the flowchart of FIG. 9. As illustrated in FIG. 9, in
step S901, the control unit 115 checks whether i=0 for variables i
in the continuous servo AF operation. If i is 0 (YES in step S901),
the processing proceeds to step S905. If i is not 0 (NO in step
S901), the processing proceeds to step S902.
[0115] In step S902, the control unit 115 checks whether a
difference between PreTime and ScanTime[i-1] is shorter than a
predetermined time set in advance. If the difference is shorter
than the predetermined time (YES in step S902), the processing
proceeds to step S903. If the difference is longer than the
predetermined time (NO in step S902), the processing proceeds to
step S905. From this, a time elapsed since a previous scan until a
current scan is found, and it is possible to determine whether a
prediction using a result of the previous scan is reliable. For
example, if it takes a time longer than the predetermined time, it
can be concluded that the prediction is not reliable.
[0116] In step S903, the control unit 115 checks whether the same
direction movement flag is TRUE. If the same direction movement
flag is TRUE (YES in step S903), the processing proceeds to step
S904. If the same direction movement flag is FALSE (NO in step
S903), the processing proceeds to step S905. Consequently, only
when it is determined that an object is moving in the same
direction in terms of distance direction, it is assumed that the
prediction is reliable. Thereby, an erroneous prediction due to
using an erroneous AF result can be reduced.
[0117] In step S904, the control unit 115 determines a result of
predictability determination to be predictable. Then, the
subroutine of the predictability determination ends. Then, the
processing proceeds to step S803. In step S905, the control unit
115 determines a result of the predictability determination to be
unpredictable. Then, the subroutine of the predictability
determination ends. Then, the processing proceeds to step S803.
[0118] Next, a subroutine of predicting the object position in step
S804 in the flowchart of FIG. 8 will be described below with
reference to the flowchart of FIG. 10 and the explanatory views of
FIGS. 11A and 11B. As illustrated in FIG. 10, in step S1001, the
control unit 115 checks whether i is smaller than 2 for variables i
in the continuous servo AF operation. If i is smaller than 2 (YES
in step S1001), the processing proceeds to step S1002. If i is
equal to or greater than 2 (NO in step S1001), the processing
proceeds to step S1003. In step S1002, the control unit 115 sets a
scan center position to a peak position of a previous scan. Then,
the subroutine of predicting the object position ends. Then, the
processing proceeds to step S807.
[0119] In step S1003, the control unit 115 checks whether is equal
to 2. In other words, in step S1003, the control unit 115 checks
whether data for predicting the moving object is two points, to
determine the case of two points, and the case of three points or
more. If i is equal to 2 (YES in step S1003), the processing
proceeds to step S1004. If i is greater than 2 (NO in step S1003),
the processing proceeds to step S1006.
[0120] In step S1004, the control unit 115 calculates a prediction
position of an object from data for the moving object prediction
for two points, as illustrated in FIG. 11A, using a first moving
object prediction formulae (1) given below, and then the processing
proceeds to step S1005. More specifically, the control unit 115
calculates a predicted position of the object at PreTime, i.e.,
PrePosition from two points of (ScanTime[0], HokanPeak[0]), and
(ScanTime[1], HokanPeak[1]).
PrePosition=(PreTime-ScanTime[0]).times.(HokanPeak[1]-HokanPeak[0])/(Sca-
nTime[1]-ScanTime[0])+HokanPeak[0] (1)
[0121] In step S1005, the control unit 115 sets the predicted
position, of the object, i.e., PrePosition calculated in step S1004
to the scan center position. Then, the subroutine of predicting the
object position ends. Then, the processing proceeds to step
S807.
[0122] In step S1006, the control unit 115 calculates a predicted
position of an object from data for predicting the moving object
for three points, as illustrated in FIG. 11B, using a second moving
object prediction formulae (2) given below, and then the processing
proceeds to step S1007. The data for predicting the moving object
for three points are (ScanTime[i-2], HokanPeak[i-2]),
(ScanTime[i-1], HokanPeak[i-1]), and (ScanTime[i], HokanPeak[i]).
Therefore, the control unit 115 calculates a predicted position,
i.e., PrePosition of the object at PreTime from the above-described
three points.
PrePosition=(t3/t2).times.{(t3-t2).times.(t2.times.Pos1-t1.times.Pos2)/t-
1/(t1-t2)+Pos2}+HokanPeak[i-2] (2)
where,
t1=ScanTime[i-1]-ScanTime[i-2]
t2=ScanTime[i]-ScanTime[i-2]
t3=PreTime-ScanTime[i-2]
Pos1=HokanPeak[i-1]-HokanPeak[i-2]
Pos2=HokanPeak[i]-HokanPeak[i-2].
[0123] In step S1007, the control unit 115 sets a predicted
position of the object, i.e., PrePosition calculated in step S1006
to a scan center position. Then, the subroutine of predicting the
object position ends. Then, the processing proceeds to step
S807.
[0124] Next, a subroutine of scanning in step S712 in the flowchart
of FIG. 7 and step S810 of the flowchart of FIG. 8 will be
described below with reference to the flowchart of FIG. 12. As
illustrated in FIG. 12, in step S1201, the control unit 15 moves
the focus lens 104 to a scan-starting position. In this process,
the scan-starting position is set at one end of the movement range
previously set.
[0125] In step S1202, the control unit 115 stores a focus
evaluation value of an image area according to an AF frame within a
shooting screen and a position of the focus lens 104 in an
arithmetic memory contained within the control unit 115, and then
the processing proceeds to step S1203.
[0126] In step S1203, the control unit 115 checks whether a lens
position of the focus lens 104 is located at a scan end position.
If the lens position is located at the scan end position (YES in
step S1203), the processing proceeds to step S1205. If the lens
position is not located at the scan end position (NO in step
S1203), the processing proceeds to step S1204. The scan end
position is set to the other end of the movement range, which is an
opposite side to one end of the movement range, as the
scan-starting position.
[0127] In step S1204, the control unit 115 moves the focus lens 104
by a predetermined amount to a predetermined direction set in
advance, and then the processing proceeds to step S1202. In step
S1205, the control unit 115 reads out in sequence a focus
evaluation value and a lens position thereof stored in the
arithmetic memory in step S1202, to calculate a peak position of
the focus evaluation value. Then, the subroutine of scanning
ends.
[0128] Next, a subroutine of the in-focus determination in step
S713 in the flowchart of FIG. 7 and step S811 in the flowchart of
FIG. 8 will be described below with reference to FIG. 13 to FIG.
16.
[0129] When a graph has a focus lens position at the abscissa axis
and a focus evaluation value at the ordinate axis, it has a hill
shape as illustrated in FIG. 13, except for special cases, such as
a conflict between far and near objects. Therefore, the imaging
apparatus 1 can perform the in-focus determination by determining
whether a focus evaluation value has a hill shape based on a
difference between a maximum value and a minimum value of the focus
evaluation value, a length of a part inclining with an inclination
equal to or greater than a constant value (Slope Thr), and the
slope of the inclining part. The result of the in-focus
determination is output with the marks "o" and "x" given as
follows:
Determined as "o": Focus adjustment of an object is possible based
on a peak position of the focus evaluation value. Determined as
"x": Contrast of an object is insufficient, or an object is located
at a distance outside distance range where scanned.
[0130] As illustrated in FIG. 13, points up to which inclination is
continued from a hill top (point A) are denoted as point D and
point E, a width between point D and point E is denoted as a width
L of the hill, a difference between focus evaluation values at
point A and point D is denoted as SL1, and a difference between
focus evaluation values at point A and point E is denoted as SL2,
and the sum of SL1+SL2 is denoted as SL.
[0131] FIG. 14 is a flowchart illustrating a subroutine of the
in-focus determination. As illustrated in FIG. 14, in step S1301,
the control unit 115 determines a maximum value and a minimum value
of focus evaluation values, and, a scan point io corresponding to
the maximum value from a result of scanning described above. Then,
the processing proceeds to step S1302.
[0132] Next, in step S1302, the control unit 115 initializes
variables L and SL to 0, where L represents a width of the hill of
a focus evaluation value, and SL represents a slope of the hill,
and then the processing proceeds to step S1303. In step S1303, the
control unit 115 checks whether a scan point io corresponding to
the maximum value in a movement range where a scanning operation
has been performed, is a farthest end position. If the scan point
is not located at the farthest end position (NO in step S1303), the
processing proceeds to step S1304. In step S1304, the control unit
115 checks a monotonic decrease in the infinite distance end
direction. If the scan point is located at the farthest end
position (YES in step S1303), the processing skips step S1304 and
then proceeds to step S1305.
[0133] Now, a processing for checking a monotonic decrease in the
infinite distance end direction in step S1304 will be described
below. As illustrated in FIG. 15, first in step S1401, the control
unit 115 initializes a counter variable i to io. Then, the
processing proceeds to step S1402.
[0134] In step S1402, the control unit 115 compares a difference
between a value d[i] of a focus evaluation value in a scan point i
and a value d[i-1] of a focus evaluation value in a scan point i-1
with a predetermined value Slope Thr set in advance. The scan point
i-1 is nearer to the infinite distance end side by one scan point
than the scan point i. If the relation is d[i]-d[i-1]>=Slope Thr
(YES in step S1402), the control unit 115 determines that a
monotonic decrease in the infinite distance end direction occurs.
Then, the processing proceeds to step S1403. On the other hand, if
the relation is not d[i]-d[i-1]>=Slope Thr (NO in step S1402),
the control unit 115 determines that a monotonic decrease in the
infinite distance end direction does not occur. Then, the
processing for checking a monotonic decrease in the infinite
distance end direction ends. Then, the processing proceeds to step
S1305.
[0135] The processing for checking a monotonic decrease in the
infinite distance end direction may be continued. In such a case,
the processing proceeds to step S1403. In step S1403, the control
unit 115 updates a variable L representing the length of a part (a
width of hill) where the focus evaluation value inclines with an
inclination equal to or greater than a specified value, and a
variable SL representing an amount of decrease in a monotonic
decrease section according to the following formulae. Then, the
processing proceeds to step S1404.
L=L+1
SL=SL+(d[i]-d[i-1])
[0136] In step S1404, the control unit 115 decrements the counter
variable i as i=i-1 to shift a point to be detected by one scan
point towards the infinite distance end side. Then, the processing
proceeds to step S1405. In step S1405, the control unit 115 checks
whether the counter variable i has become a value at the farthest
end position (=0) in a scanned predetermined movement range. If the
value of the counter variable i is 0, that is, the start point to
detect a monotonic decrease reaches the farthest end position in
the scanned predetermined movement range (YES in step S1405), the
processing for checking a monotonic decrease in the infinite
distance end direction ends. Then, the processing proceeds to step
S1305. In a manner described above, the imaging apparatus 1 checks
a monotonic decrease of a focus evaluation value in the infinite
distance end direction from i=io.
[0137] Referring back to FIG. 14, a continued subroutine of the
in-focus determination will be described below. In step S1305, the
control unit 115 checks whether a scan point io corresponding to a
maximum value is the position of the closest distance end in a
scanned predetermined movement range. If the scan point io is not
the closest distance end position (NO in step S1305), the
processing proceeds to step S1306. In step S1306, the control unit
115 checks a monotonic decrease in the closest distance end
direction. If the scan point io is the closest distance end
position (YES in step S1305), the processing skips step S1306 and
then proceeds to step S1307.
[0138] Now, processing for checking a monotonic decrease in the
closest distance end direction in step S1306 will be described
below. As illustrated in FIG. 16, first in step S1501, the control
unit 115 initializes a counter variable i to io, and then the
processing proceeds to step S1502.
[0139] In step S1502, the control unit 115 compares a difference
between a value d[i] of a focus evaluation value in a scan point i
and a d[i+1] of a focus evaluation value in a scan point i+1 with a
predetermined value Slope Thr. The scan point i+1 is nearer to the
closest distance end side by one scan point than the scan point i.
If the relation is d[i]-d[i+1]>=Slope Thr, (YES in step S1502),
the control unit 115 determines that a monotonic decrease in the
closest distance end direction occurs. Then, the processing
proceeds to step S1503. On the other hand, if the relation is not
d[i]-d[i+1]>=Slope Thr (NO in step S1502), the control unit 115
determines that a monotonic decrease in the closest distance end
direction does not occur. Then, the processing for checking a
monotonic decrease in the closest distance end direction ends.
Then, the processing proceeds to step S1307.
[0140] The processing for checking a monotonic decrease in the
closest distance end direction may be continued. In such a case,
the processing proceeds to step S1503. In step S1503, the control
unit 115 updates the variable L representing the length of a part
(a width of hill) where the focus evaluation value inclines with an
inclination equal to or greater than a constant value, and the
variable SL representing an amount of a decrease in a monotonic
decrease section according to the following formulae: Then, the
processing proceeds to step S1504.
L=L+1
SL=SL+(d[i]-d[i+])
[0141] In step S1504, the control unit 115 increments the counter
variable i as i=i+1 to shift a point to be detected by one scan
point towards the closest distance end side. Then, the processing
proceeds to step S1505. In step S1505, the control unit 115 checks
whether the counter variable i has become a value (=N) at the
closest distance end position in a scanned predetermined movement
range. If the value of the counter variable i reaches N, that is,
the start point to detect a monotonic decrease reaches the closest
distance end position in the scanned predetermined movement range
(YES in step S1505), the processing for checking a monotonic
decrease in the closest distance end direction ends. Then, the
processing proceeds to step S1307. As described above, the imaging
apparatus 1 checks a monotonic decrease of focus evaluation value
in the closest distance end direction from i=io.
[0142] Referring back to FIG. 14, a continued subroutine of the
in-focus determination will be described below. When the
above-described processing for checking a monotonic decrease in the
infinite distance end direction and the closest distance end
direction ends, the control unit 115 compares various coefficients
with respective threshold values to check whether the calculated
focus evaluation value has a hill shape, thus determining as "o" or
"x". More specifically, the control unit 115 determines as "o" or
"x" by the processing in steps S1307 to S1309 described below.
[0143] In step S1307, the control unit 115 checks whether the scan
point io corresponding to a maximum value of focus evaluation
values is the closest distance end in a scanned predetermined
movement range. If the scan point io is the closest distance end,
the control unit 115 checks whether a difference between the value
d[n] of a focus evaluation value in a scan point n of the closest
distance end and a value d [n-1] of a focus evaluation value in a
scan point n-1 is equal to or greater than the predetermined value
Slope Thr. The scan point n-1 is nearer to the infinite distance
end side by one scan point than the scan point n. If the scan point
io is the closest distance end, and the difference is equal to or
greater than the predetermined value Slope Thr (YES in slope 1307),
the processing proceeds to step S1311. If not both of these
conditions are satisfied (NO in slope 1307), the processing
proceeds to step S1308.
[0144] In step S1308, the control unit 115 checks whether the scan
point io corresponding to the maximum value of focus evaluation
values is the farthest end in a scanned predetermined movement
range. If the scan point io is the farthest end, the control unit
115 checks whether a difference between value d[0] of a focus
evaluation value in the scan point 0 of the farthest end and a
value d[1] of a focus evaluation value in the scan point 1 is equal
to or greater than the predetermined value Slope Thr. The scan
point 1 is nearer to the closest distance end side by one scan
point than the scan point 0. If the scan point is the farthest end
and the difference is equal to or greater than the predetermined
value Slope Thr (YES in step S1308), the processing proceeds to
step S1311. If not both of these conditioned are satisfied (NO in
step S1308), the processing proceeds to step S1309.
[0145] In step S1309, the control unit 115 checks whether the
length of a part L inclining with a inclination equal to or greater
than a constant value is equal to or greater than a set in advance
predetermined value Lo. If the length L is equal to or greater than
the predetermined value Lo, the control unit 115 checks whether the
average value SL/L is equal to or greater than the set in advance
predetermined value SLo/Lo, and the difference between the maximum
value and the minimum value of the focus evaluation values is equal
to or greater than the set in advance predetermined value. If the
length L of a inclined part is equal to or greater than the
predetermined value Lo, and the average value SL/L of inclination
of the inclined part is equal to or greater than the predetermined
value SLo/Lo, and the difference between the maximum value and the
minimum value of the focus evaluation value is equal to or greater
than the predetermined value (YES in step S1309), the processing
proceeds to step S1310. On the other hand, if not all of these
conditions described above are satisfied (NO in step S1309), the
processing proceeds to step S1311.
[0146] In step S1310, the control unit 115 sets a determined result
to "o" determination, since all of the determination conditions in
steps S1307 to S1309 are satisfied, the calculated focus evaluation
value has a hill shape, and the focus adjustment of an object is
available. In step S1311, the control unit 115 sets a determined
result to "x" determination since either of determination
conditions in steps S1307 to S1309 is not satisfied, the calculated
focus evaluation value does not have a hill shape, and the focus
adjustment to an object is not available. As described above, the
imaging apparatus 1 performs the in-focus determination in step
S713 in the flowchart of FIG. 7 and step S811 in the flowchart of
FIG. 8.
[0147] Next, a subroutine of the shooting operation in step S215 in
the flowchart of FIG. 2 will be described below with reference to
the flowchart of FIG. 17. As illustrated in FIG. 17, in step S1701,
the control unit 115 measures an object luminance, and then the
processing proceeds to step S1702. In step S1702, the control unit
115 controls the AE processing unit 103 according to the object
luminance measured in step S1701, and performs exposure to the
image sensor 108. Then, the processing proceeds to step S1703.
[0148] An object image formed on an image plane of the image sensor
108 by the exposure in step S1702 is subjected to a photoelectric
conversion, and is output to the A/D conversion unit 109 as an
analog signal (analog image data). In step S1703, in the A/D
conversion unit 109, analog image data from the image sensor 108 is
converted into digital image data and output, after pre-processing
such as output noise elimination and nonlinear processing of the
image sensor 108.
[0149] In step S1704, the control unit 115 converts digital image
data output from the A/D conversion unit 109 to appropriate image
data by a white balance adjustment of the WB processing unit 111
and image processing of the image processing unit 110, and then the
processing proceeds to step S1705. In step S1705, the control unit
115 performs image format conversion to a format such as JPEG with
respect to digital image data converted by the format conversion
unit 112, and subsequently temporarily stores the image data on the
DRAM 113. Then, the processing proceeds to step S1706. In step
S1706, the control unit 115 stores data within the DRAM 113 on a
recording medium such as a memory card by the image recording unit
114. Then, the subroutine of the shooting operation ends.
[0150] As described above, in the present exemplary embodiment, if
it is determined that an object is not moving in the distance
direction, a useless lens movement can be reduced by stopping the
focus lens until the object moves in the next moment and a distance
from the object has changed. For this reason, deterioration of
visual quality of the EVF display, and battery consumption can be
reduced. An in-focus position with a low reliability or erroneous
in-focus position may have been obtained. In such a case, further,
in the present exemplary embodiment, the cases that a focusing
while tracking the object becomes unavailable can be reduced by
refraining from performing prediction of the object position.
[0151] While the present invention has been described with
reference to exemplary embodiments, it is to be understood that the
invention is not limited to the disclosed exemplary embodiments.
The scope of the following claims is to be accorded the broadest
interpretation so as to encompass all modifications, equivalent
structures, and functions.
[0152] This application claims priority from Japanese Patent
Application No. 2008-237187 filed Sep. 16, 2008, which is hereby
incorporated by reference herein in its entirety.
* * * * *