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Description  |
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BACKGROUND OF THE INVENTION
1. Field of the Invention:
This invention relates to a photographic optical system controlling
apparatus used in video cameras etc., which performs lens focusing control
and exposure control based on image signals obtained from an imaging
element.
2. Description of the Related Art
Heretofore, there have been proposed various types of automatic focusing
system used as an optical controlling means of a photographic apparatus.
Among them, the most popular method, using an image signal obtained from
an imaging means, is to pick up the high-frequency component in the image
signal and to obtain its differential value, and then to drive a lens in a
direction which allows the absolute value of the differential value to be
increased. An object image obtained through the lens system is most
sharply outlined when in focus. Further and being out of focus in any
direction causes fuzz. Therefore, the output image signal of the video
camera used to photograph this object image has a maximum level of its
high-frequency component when in focus.
The image can then be brought into focus by controlling the position of the
lens such that the high-frequency component of the image signal becomes
maximum. Such a focusing method is called the "climbing serbo method".
FIG. 12 of the accompanying drawings shows a typical automatic focusing
apparatus using the climbing serbo method. In FIG. 12, the numerals
designate respectively: 2, a lens; 4, an imaging element for converting
the image, formed on the imaging surface through the lens, into electrical
signals; 6, a pre-amplifier for amplifying the image signal output from
the imaging element 4; 8, signal processing circuit for converting the
output signal from the pre-amplifier 6 into a standardized signal like an
a NTSC signal; 10, a band-pass-filter (hereinafter referred as "BPF") for
picking up only the high-frequency component of the output signal from the
pre-amplifier 6; 12, a gate circuit for selecting only the signal in the
focusing detecting area from the output signals of the BPF 10 forming one
screen (one field or one frame), and allowing the selected signal to pass
through; 14, wave-detecting circuit for wave-detecting the output of the
gate circuit 12; 16, motor driving circuit for driving the lens driving
motor based on the output of the wave-detecting circuit 14; and 18, a lens
driving motor for controlling the focusing operation by moving the lens
position.
According to this composition, the image formed on the imaging surface of
the imaging element through the lens 2 is converted into electrical
signals, and is then amplified to a predetermined level by the
pre-amplifier 6. The high-frequency component of the image signal varies
in accordance with the lens position, namely the focusing condition of the
object. Specifically, the high-frequency component increases as the lens
moves closer to the in focus position, and becomes maximum at the focus
point.
FIG. 13 shows the variation of the high-frequency component in the image
signal with respect to the lens position. As seen from the FIG.13, the
high-frequency component becomes maximum at the focus point, and decreases
as the lens moves away from the focus point. Accordingly, it is understood
that the focused state can be obtained by positioning the lens at a
position rendering the maximum high-frequency component.
As another optical system controlling device of a photographic apparatus,
an exposure controlling device is known. The main section of such a
photographic apparatus is shown in FIG. 14.
In FIG. 14, the numerals designate respectively: 20, a lens; 22, an
exposure controlling circuit for controlling the quantity of light
incident from the lens 20; 24, an imaging element for converting the image
formed on the imaging surface through the lens 20 into an electrical
signal; 26, an amplifier for amplifying the image signal output from the
imaging element 24; 28, an AGC circuit for ensuring that the output signal
from the amplifier 26 is constant; 30, a signal processing circuit for
converting the output from the AGC circuit into a standardized (e.g. NTSC)
image signal; 32, an image signal output from the signal processing
circuit 30; 34, a photometric area determining circuit for determining the
photometric area; 36, a gate circuit for allowing the output signal of the
amplifier 26 to pass through in accordance with the timing of the
photometric area, being the output of the photometric area determining
circuit 34; 38, a signal level detecting circuit for detecting the
luminocity information output from the gate circuit 36; 40, an exposure
detecting signal generated in the signal level detecting circuit 38; and
42, an exposure control target value set by an external device.
In operation of the apparatus shown in FIG. 14, the incident light,
projecting into the lens 20 and exposure controlled by the exposure
controlling circuit 22, forms an image on the imaging element and is
converted into electrical signals. The output of the imaging element 24 is
amplified in the amplifier 26 and input to a AGC circuit 28. The AGC
circuit 28 controls the gain of the signal to make its output level
constant, which is output as an image signal 32 through a signal
processing circuit 30. Meanwhile, a photometric area determining circuit
34 outputs signals corresponding to the timing of a photometric frame. The
output of the amplifier 26 is input to the signal level detecting circuit
38 through a gate circuit 36 in accordance with the timing. The signal
level detecting circuit 38 generates an exposure detecting signal, being
information of light intensity. The exposure controlling circuit 22
controls the exposure such that the level of the exposure detecting signal
40 equals an exposure control target value 42.
Next, an emphasized photometric operation provided with a photometric frame
will be described hereinafter. In general, the upper part of the
background of an image usually consists of a high luminace image like the
sky. Therefore, if the exposure controlling is performed in accordance
with the luminance level of such a high-luminance background, the image
will become a so-called backlight shot causing the main object e.g. face
of a person, to become darkened. To cope with this problem, there has been
performed exposure control by providing a photometric frame 44 positioned
at the lower central part of the screen by a photometric area generating
circuit 34, and then by performing an emphasized photometric operation in
the photometric frame using image signals in the frame by a signal level
detecting circuit 38, as shown in FIG. 15(a). Alternatively, another type
of exposure controlling operation may be carried out by dividing the
screen into a plurality of portions, and weighting the luminance
information obtained from each of the divided portions, as shown in FIG.
15(b).
According to the aforementioned conventional automatic focusing device,
however, a disadvantage has arisen: the focusing detecting area is fixedly
determined at the center of the screen, so there has been a fear of
misfocusing on other objects, which should not be focused on and are
accidentally located at the center of the screen, when the position of the
object to be focused and having been at the center changes owing to the
movement of the camera etc.. In order to avoid such an inconvenience,
Japanese Patent Laid-Open No. Sho 64-49484 or Japanese Patent Laid-Open
No. Sho 64-71382 teaches the use of a variable gate circuit. However since
the area determinating operation by the variable gate circuit is carried
out basically by the same method as the focusing state detecting method,
if the focusing operation malfunctions, the gate area determination
operation will suffer degradation in accordance therewith.
Also, according to the aforementioned conventional exposure controlling
device, a disadvantage has arisen: the emphasized photometric area is
fixedly determined in the screen irrespective of the weighting value.
Therefore, even if the position of the main object in the screen changes
due to the movement of the camera etc., the exposure control operation is
carried out to be optimum for any object located in the photometric area,
not for the main object.
SUMMARY OF THE INVENTION
It is therefore an object of this invention to provide a photographic
optical system controlling apparatus comprising an automatic focusing
device capable of: continuously focusing on the main object irrespective
of its positional change in the screen; designating the gate area;
identifying the gate area so as to easily correct and change the input
operation of the main object; and accurately detecting the movement of the
main object.
Also, it is another object of this invention to provide a photographic
optical system controlling apparatus comprising an exposure controlling
device capable of: controlling the exposure for the main object to be
optimum irrespective of the positional change of the main object in the
screen; designating the photometric area; identifying the gate area so as
to easily correct and change the input operation of the main object; and
accurately detecting the movement of the main object.
According to this invention, a photographic optical system controlling
apparatus for automatically controlling the focusing operation of a
photographic optical system based on an image signal obtained in a
focusing detecting area designated on a photographic screen, said
apparatus comprising: a motion vector detecting means for detecting the
motion of an image from the correlation of two time-continuous two image
data; and a gate area controlling means which detects the main object from
the output of said motion vector detecting means, and controls a gate area
to follow to the motion of the main object.
The motion vector detecting means detects the motion of the image
(direction and magnitude) and changes the gate area in accordance
therewith.
Further, according to this invention, a photographic optical controlling
apparatus for controlling exposure based on an image signal obtained at a
photometric area designated on a photographic screen, said apparatus
comprising: a motion vector detecting means for detecting the motion of an
image from the correlation of two time continuous image data; and a
photometric area controlling means which detects the motion of the main
object from the output of said motion vector detecting means, and causes
the photometric area to follow the motion of the main object.
The motion vector detecting means detects the motion of the image
(direction and magnitude) and changes the photometric area by in
accordance therewith.
The above and other advantages, features and additional objects of this
invention will be manifest to those versed in the art upon making
reference to the following detailed description and the accompanying
drawings in which a preferred structural embodiment incorporating the
principles of this invention is shown by way of an illustrative example.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram showing an embodiment of an automatic focusing
device according to this invention;
FIG. 2 is a block diagram showing an embodiment of an exposure controlling
device according to this invention;
FIG. 3 is a block diagram showing an example of the motion vector detecting
circuit in FIGS. 1 and 2;
FIG. 4 is a schematic view showing the relationship between the block and a
typical point in the motion vector detecting circuit;
FIGS. 5-9 are views showing the features of the main object's magnitude
judging device and the area changing means;
FIG. 10 is a schematic view showing the structure and the operation of the
pointing device;
FIG. 11 is a schematic view showing the composition and the operation of
the gate area superimposing circuit;
FIG. 12 is a block diagram showing a conventional automatic focusing
device;
FIG. 13 is a graphic diagram showing the relationship between the detected
high-frequency component level and the feeding amount of the lens;
FIG. 14 is a block diagram showing a conventional exposure controlling
device;
FIG. 15 is a schematic view showing a photometric frame for the screen
frame and an example of a screen-dividing method in the emphasized
photometric operation.
DETAILED DESCRIPTION
The principles of this invention are particularly useful when embodied in
an automatic focusing device and in an exposure controlling device used in
a photographic camera etc.
FIG. 1 is a block diagram showing an automatic focusing device according to
this invention. In FIG. 1, the numerals respectively designate: 58, a
lens; 60, an imaging element for converting the image formed on the
imaging surface through the lens 58 into an electrical signal; 62, a
pre-amplifier for amplifying the image signal output from the imaging
element 60; 64, a processing circuit for converting the output from the
pre-amplifier 62 into a standardized (e.g. NTSC) image signal; 66, a BPF
(band-pass filter) for extracting the high-frequency component from the
output signal of the pre-amplifier 62; 68, a motion vector detecting
circuit for detecting the motion of the image from two time continuous
image frames; 70, a gate area controlling circuit for changing the gate
area in accordance with the output of the motion vector detecting circuit;
72, a gate area superimposing circuit for superimposing the gate area on
the video signal; 74, a view finder for watching the image with the gate
area superimposed thereon; 76, a pointing device for inputting the
corrections or changes of the gate area to the gate area controlling
circuit 70 thereby constituting a gate area designating device; 78, a gate
circuit for selecting only the signal at the focusing detecting area from
the signals corresponding to the one screen (or one field or one frame)
and for allowing the selected signals to pass therethrough; 80, a
wave-detecting circuit for wave-detecting the output of the gate circuit
78; 82, a motor driving circuit for driving a lens driving motor; 84, a
lens driving motor for moving the lens position to control the focusing.
Similar to the aforementioned conventional device, the image formed on the
imaging surface of the imaging element by the lens 58 is: converted into
electrical signals; amplified to a predetermined level by the
pre-amplifier 62; converted into a video signal by the processing circuit
64. Also, the lens is stopped at a position where the maximum
high-frequency component of the video signal is achieved, thereby
providing the desired focused state.
The characteristics of this invention are the ability to detect the motion
of the main object and to move the gate area in accordance therewith.
Namely, an automatic focusing operation is carried out which follows the
movement of the main object.
In order to enhance the operation of the automatic focusing device, there
are also provided a pointing device 76 for inputting gate area-corrections
or changes by the user, and a gate area superimposing circuit 72 for
superimposing the gate area on the video signal to allow the user to
visually recognize the gate area on the screen.
FIG. 2 is a block diagram showing an exposure controlling device according
to this invention. In FIG. 2, the numerals designate respectively: 86, a
lens; 88, an exposure controlling device for controlling the amount of
incident light which passes through the lens 86; 90, an imaging element
for converting the image formed on the imaging surface by the lens 86 into
electrical signals; 92, an amplifier for amplifying the image signal
output from the imaging element 90; 94, an ACG circuit for controlling the
gain the amplifier 92 so that the output will be a predetermined level;
96, a signal processing circuit for converting the output signal from the
AGC circuit 94 into a standardized signal like NTSC; 98, an image signal
output from the signal processing circuit 96; 100, a gate circuit for
allowing only the output signals corresponding to the photometric area
from the amplifier 92; 102, a signal level detecting circuit for detecting
the brightness information of the output signal from the gate circuit 100;
104, an exposure detecting signal generated in the signal level detecting
circuit 102; 106, an exposure controlling target value which is set by an
external apparatus; 108, a motion vector detecting circuit for detecting
the motion of the image from two time continuous screens; 110, a
photometric area controlling circuit for changing the photometric area in
accordance with the output of the motion vector detecting circuit 108;
112, a photometric area superimposing circuit for superimposing the
photometric area on the video signal for display; 114, a view finder for
visually recognizing the image on which the photometric area is
superimposed; 116, a pointing device for inputting the correction and
change of the photometric area to the photometric area controlling circuit
110.
In operation, the incident light through the lens 86 is exposure-controlled
by the exposure controlling circuit 88, and thereafter converted into
electrical signals and amplified by the amplifier 92. The output level of
the amplified signal is kept constant by the AGC circuit 94, and is
transmitted as an image signal 98 through the signal processing circuit
96. The output of the amplifier 92 is input to the signal level detecting
circuit 102. The exposure controlling circuit 88 controls the exposure
such that the level of the exposure detecting signal 104 equals the
exposure controlling target value 106.
The characteristics of this invention are the ability to detect the motion
of the main object by the motion vector detecting circuit 108 and to move
the photometric area following the movement of the main object by the
photometric area controlling circuit 110. Namely, the exposure is
controlled in accordance with the motion of the main object. Further, the
pointing device 116 is provided to allow the user to input the correction
and change of the photometric area, and the photometric area superimposing
circuit 112 is provided for superimposing the gate area on the video
signal to allow the user to visually recognize the photometric area.
The motion vector detecting circuit 68, 108 will now be explained referring
to the FIGS. 3 and 4.
In order to detect the amount of movement the image between a pair of
frames, it is ideal to compute what amount the image has moved by in which
direction, for all the pixels in the image, which renders the best
detecting accuracy of the motion vector. However, this naturally requires
enormous hardware and performance time and is not easily realized. In
general, therefore, only a part of all the pixels (hereinafter referred as
representative pixels) have been used to determine the motion vector of
the entire screen.
FIG. 3 is a block diagram showing a well-known represents the pixel
calculating circuit. FIG. 4 represents the relationship between the block
of the image in the conventional device in FIG. 2 and the representative
points. A one-field image is divided into a predetermined number of blocks
120, each of which is provided with a representative point Rij 124 at the
center thereof. In each block, the level difference is taken between the
representative point in the block just before and all the pixels Si+x j+y
126 in the subject block.
In FIG. 3, an input image signal A is initially converted in the A/D
converter 128 to a digital signal. A predetermined pixel in the block 120
to be the representative point is written in the representative memory 132
through the latch circuit 136. The data stored in the representative
memory 132 is read out with a delay of one frame, and then transmitted to
the absolute value circuit 138 through the latch circuit 134. On the other
hand, the A/D converted image signal data is transmitted to the absolute
value circuit 138 through the latch circuit 136. The representative point
signal (B) and the pixel signal (C) of the present frame output from the
latch circuit 136 are input for calculation in the absolute value circuit
138 to render an absolute value of difference. Such a calculation is
carried out for each block. This output signal (D) of the absolute value
circuit 138 is then supplied to the gate circuit 146 for the selection of
only the signals in the vector detecting area. The selected signals are
sequentially added to the tables corresponding to the same address of the
pixels in each block of the accumulating adding circuit 142. The added
result of the table is input to the table value comparing circuit 144
where the amount and direction of movement of the image position in a
frame, namely the motion vector, can be obtained from the address of the
minimum added result.
In short, the absolute value of the difference between the representative
point Rij and the signals Si+x j+y having the relationship of horizontal
direction x, vertical direction y with the representative point Rij.
Thereafter, accumulative adding table Dxy is obtained by performing an
adding operation of the xy of the same positional relationship to each of
the representative points. Then, Dxy will be expressed as follows:
Dxy=.SIGMA..sub.i .SIGMA..sub.j .vertline.Rij-Si+xj+y.vertline.
The x and y of the minimum value is designated as a horizontal and vertical
motion vector.
When the main object moves uniformly on the major part of the screen, the
larger the number of blocks, the greater the detecting accuracy of the
motion vector. However, if the main object moves only at a part of the
screen, the detecting accuracy of the motion vector will be improved only
from the adjacent frames of the main object (gate area) rather than from
all the blocks.
Therefore, the movement of the main object can be accurately detected by
adaptively changing the number of blocks to be accumlatively added in
accordance with the contents of the image.
In this case, for example, it is possible to judge if the image occupies
all or only a part of the screen from the distribution of the histogram of
the signal level at the representative point. Specifically, it is
calculated what percentage does the scope of averaged value.+-.of the
signal level at the representative points of the focusing detecting area
or the photometric area occupy of all the representative points. When the
occupying rate is high, this means that the main object occupies the
majority of the screen. Meanwhile when the occupying rate is low, this
means that the main object occupies only a part of the screen. This is
hereby defined as a judging device. It is assumed that the motion vector
detecting area equals the focusing detecting area or the photometric area,
that there are provided a block counter, area start register (hereinafter
referred as "RSR"), and an area end register (hereinafter referred as
"RER") in both the horizontal and vertical directions, and that the block
counter designates the block over RSR and below RER as a detecting area.
When the detecting area is moved while maintaining its size on detecting
the motion vector, the values of RSR and RER are simultaneously increased
and decreased. When the detecting area is enlarged on judging the
magnitude of the object, the RSR is decreased while the RER increased.
When the detecting area is made small on judging the magnitude of the
object, the RSR is increased while the RER decreased. This is defined as
an area changing device.
These will now be described more specifically hereinafter. For instance,
the histogram generating device 146 generates a density histogram of the
signal level at the representative points, while the main object's
magnitude judging device 148 judges the magnitude of the object from the
distribution of the density histogram, thereby outputting a object
magnitude signal F. Specifically, the histogram generating device 148
computes at what percentage of all the representative points are the scope
of average.+-.of the signal level of the representative points at the
focusing detecting area or the photometric area. The main object's
magnitude judging device judges that the main object occupies the majority
of the screen when the occupying rate is high, and that the main object
occupies only a part of the screen when the occupying rate is low.
For example, when the density histogram of the signal level at the
representative point is as shown in FIG. 5, namely when the average value
of signal level at the representative points of the focusing detecting
area or the photometric area occupies only 20% of all the representative
points, it is judged that the main object occupies only a part of the
screen. Meanwhile when the average value of signal level at the
representative points of the focusing detecting area or the photometric
area occupies more than 37% of all the representative points, it is judged
that the main object occupies the majority of the screen.
Next, it will be described how the focusing detecting area or the
photometric area is to be generated in the gate area controlling circuit
78 or in the photometric area controlling circuit 110.
In the gate area controlling circuit 78 or in the photometric area
controlling circuit 110, the block counter, the RSR and the RER are
provided for both the horizontal and vertical directions. The block
counter designates the block over RSR and below RER as a detecting area,
and also designates the logical product of the horizontal detecting area
with the vertical detecting area as a focusing detecting area or a
photometric area.
If the motion vector signal E, indicating that the object has moved in a
right-hand direction, is input when the horizontal RSR, the horizontal
RER, the vertical RSR, and the vertical RER are set as shown in FIG. 7 so
as to generate a focusing detecting area or a photometric area. The
focusing detecting area or the photometric area can be moved in accordance
therewith by increasing the value of both the horizontal RSR and the
horizontal RER simultaneously, as shown in FIG. 8. This is the function of
the area changing device.
When an object magnitude signal F, indicating that the object occupies the
majority of the screen, is input when the state of the photometric area is
as shown in FIG. 7, the focusing detecting area or the photometric area
can be enlarged by increasing the horizontal RER and the vertical RER as
shown in FIG. 9.
Next, the pointing device 76, 116 will be described referring to the FIG.
10. As a pointing device used in this embodiment, from the standpoint of
handling, it is preferable to select such a pointing device that is
capable of directly ordering movement in the direction of up, down, left,
and right (x and y directions), e.g. a key switch in the four directions
as shown in FIG. 10(a), a joy stick as shown in FIG. 10(b), or a roller
ball as shown in FIG. 10(c). In general, a roller ball outputs two signals
for a single axis (e.g. as shown in FIG. 10(d), XA, XB for the x axis and
YA, YB for the y axis). The movement is dictated by the phase relationship
of the two signals.
Now referring to FIG. 11, the gate area superimposing circuit or the
photometric area superimposing circuit 72, 112 will now be described
hereinafter. In FIG. 11(a), the gate area superimposing circuit or the
photometric area superimposing circuit 72, 112 comprises a clamp circuit
72a, 112a, partial pressure variable resistance 72b, 112b, and a switching
circuit 72c, 112c. At the portions G, H, I and J of this circuit, the
waveforms as shown in FIG. 7(b) with the same codes would appear. The code
I indicates a timing signal according to the photometric area output from
the photometric area controlling circuit 110. In operation, the video
signal clamped in the clamp circuit 72, 112 is switched to a predetermined
DC level of H at a superimpose timing. The superimposed signal J will be
transmitted to a view finder etc. An example of an image to be displayed
on the view finder is shown in FIG. 11(c) with the designation of K. This
display area K can move in the up, down, left and right directions
depending on the detected motion vector and the command supplied from the
pointing device.
As mentioned above, according to this invention, since the gate area or the
photometric area can be changed, the focusing or the exposure controlling
operation can be carried out accurately following the motion of the main
object irrespective of the positional change of the object in the screen.
Further, the gate area or the photometric area can be designated easily by
the gate area or the photometric area designating device, the user can
visually recognize the gate or the photometric area by the gate area or
the photometric area superimposing device, and furthermore the motion of
the main object can be accurately detected by the area changing device.
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