U.S. patent number RE31,370 [Application Number 06/072,666] was granted by the patent office on 1983-09-06 for system for exposure measurement and/or focus detection by means of image sensor.
This patent grant is currently assigned to Canon Kabushiki Kaisha. Invention is credited to Fumio Ito, Tadashi Ito, Yukio Mashimo, Nobuaki Sakurada, Nobuhiko Shinoda.
United States Patent |
RE31,370 |
Mashimo , et al. |
September 6, 1983 |
System for exposure measurement and/or focus detection by means of
image sensor
Abstract
The present invention relates to a system for exposure
measurement and/or focus detection by means of image senser such as
photo diode array (MOS image senser), CCD (charge coupled devices)
consisting of a plural number of adjacently disposed respectively
integrated fine light sensing elements whereby the image pattern of
the object is scanned purely electrically in such a manner that the
then obtained output of each light sensing element is converted
into a digital value one after another for processing.
Inventors: |
Mashimo; Yukio (Tokyo,
JP), Sakurada; Nobuaki (Kanagawa, JP), Ito;
Tadashi (Kanagawa, JP), Ito; Fumio (Kanagawa,
JP), Shinoda; Nobuhiko (Tokyo, JP) |
Assignee: |
Canon Kabushiki Kaisha (Tokyo,
JP)
|
Family
ID: |
27289228 |
Appl.
No.: |
06/072,666 |
Filed: |
September 5, 1979 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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Reissue of: |
563462 |
Mar 31, 1975 |
04047187 |
Sep 6, 1977 |
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Foreign Application Priority Data
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Apr 1, 1974 [JP] |
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49-36790 |
Apr 1, 1974 [JP] |
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49-36791 |
Apr 1, 1974 [JP] |
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49-36792 |
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Current U.S.
Class: |
396/110; 356/222;
250/201.8 |
Current CPC
Class: |
G03B
7/0807 (20150115); G03B 7/097 (20130101); G03B
7/087 (20130101); G02B 7/36 (20130101); G03B
7/091 (20130101); G03B 7/0805 (20130101); G08B
3/10 (20130101) |
Current International
Class: |
G03B
7/08 (20060101); G03B 7/091 (20060101); G02B
7/36 (20060101); G08B 3/10 (20060101); G08B
3/00 (20060101); G03B 007/08 () |
Field of
Search: |
;355/38,55-59,68
;354/23D,25,31,43,44,50,51 ;352/140 ;250/201,204,209,211J ;356/222
;357/24 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Rubinson; G. Z.
Assistant Examiner: Brady; W. J.
Attorney, Agent or Firm: Toren, McGeady and Stanger
Claims
What is claimed is:
1. An exposure measurement system comprising;
a plurality of photoelectric converting elements each for
converting a portion of a light beam into an electrical signal
corresponding to a portion of the light beam,
scanning means electrically coupled with said elements for sensing
the outputs of the elements one after another,
digital converting means coupled to said scanning means for
converting the sensed outputs of the photoelectric converting
elements into digital signals,
a processing device coupled to said digital converting means for
processing the output of the photoelectric converting elements
converted into digital values by means of the digital converting
means in accordance with a predetermined estimation function so as
to determine an exposure value.[...]. .Iadd.and
control means for controlling the processing operation of said
processing device, said control means being operable for causing
the processing device to select optional elements whose outputs are
to be utilized for the determination of the exposure value.
.Iaddend.
2. An exposure measurement system in accordance with claim 1,
further comprising;
an indication means electrically coupled to the processing device
for indicating the exposure value on the basis of the exposure
measurement information produced by the processing device.
3. An exposure measurement system in accordance with claim 1, said
processing device comprising;
an addition circuit electrically connected with the digital
convertng means for summing a plurality of the outputs of the
photoelectrical converting elements converted into digital
value,
a division circuit electrically coupled to the addition circuit for
dividing the value obtained from the addition circuit by the number
of the elements whose outputs have been summed by the addition
circuit,
a processing circuit electrically coupled to the division circuit
for processing the exposure value in accordance with the output
value of the division circuit.
4. An exposure measurement system in accordance with claim 1, said
processing device comprising;
a first addition circuit for summing all the outputs of the
photoelectric converting elements converted into digital values,
said circuit being electrically coupled to the digital converting
means,
a first division circuit for dividing the value obtained from the
first addition circuit by the total number of the elements, said
circuit being electrically coupled to the first addition
circuit,
a second addition circuit for summing a predetermined number of the
outputs of the photoelectric converting elements converted into
digital values less than the total number of the outputs of the
photoelectric converting elements converted in digital values, said
circuit being electrically coupled to the digital converting
means,
a second division circuit for dividing the value obtained from the
second addition circuit by the number of the elements whose outputs
have been summed by the second addition circuit, said circuit being
electrically coupled to the second addition circuit,
selection means electrically coupled to both of the division
circuits for selecting the value from the second division circuit
when the difference between the value from the first division
circuit and that from the second division circuit is larger than a
predetermined value, and for selecting the value from the first
division circuit when the difference is smaller than the
predetermined value,
a processing circuit for processing the exposure value on the basis
of the output value selected by the selection means, said circuit
being electrically coupled to the selection means.
5. An exposure measurement system in accordance with claim .[.5.].
.Iadd.4.Iaddend., further comprising:
switch means for actuating at least one of said first addition and
division circuits and second addition and division circuits, said
switch means being electrically coupled to the first addition and
division circuits and second addition and division circuits.
6. An exposure control system comprising
a plurality of photoelectric converting elements each for
converting a portion of a light beam into an electrical signal
corresponding to a portion of the light beam.
scanning means electrically coupled with said elements for sensing
the outputs of the elements one after another,
digital converting means coupled to said scanning means for
converting the sensed outputs of the photoelectric converting
elements into digital signals, .Iadd.
control means for controlling the processing operation of said
processing device, said control means being operable for causing
the processing device to select optional elements whose outputs are
to be utilized for the determination of the exposure value, and
.Iaddend.
a processing device coupled to said digital converting means for
processing the output of the photoelectric converting elements
converted into digital values by means of the digital converting
means in accordance with a predetermined estimation function so as
to determine an exposure value, and
exposure adjusting means electrically coupled to the processing
device for adjusting the exposure value on the basis of the
exposure measurement information produced by the processing
device.
7. An exposure measurement system for a camera comprising;
photoelectric converting means for converting light beam into
electrical signals, said means being arranged in the path of the
light beam coming from a photographic scene to be photographed by
the camera and comprising a number of photoelectric converting
elements for producing the electrical outputs corresponding to the
brightness of the photographic scene,
series detecting means for sequentially sensing the outputs of the
photoelectric converting elements, said means being electrically
coupled to the photoelectric converting means and sensing the
outputs of the photoelectric converting elements in sequence and
transmitting the outputs of the photoelectric converting elements
one by one,
digital converting means for successively converting the successive
outputs of the detecting means into digital values, said means
being electrically coupled to the output terminal of the
photoelectric converting means,
a processing device for determining the exposure value by
processing the outputs converted into digital values by means of
the digital converting means in accordance with a predetermined
estimation function, so as to determine the exposure value, said
device comprising;
addition means for summing a plurality of the outputs of the
photoelectric converting elements converted into digital values of
the photoelectric converting elements, said means being
electrically coupled to the digital converting means,
division means for dividing the value obtained from the addition
means by the number of the elements whose outputs have been summed
by the addition means, said means being electrically coupled to the
addition means,
processing means for processing the exposure value on the basis of
the value obtained from the dividing means, said means being
electrically coupled to the dividing means.
8. A camera capable of an exposure measurement by converting the
light beam coming from the photographic scene through a
photo-taking optical system into electrical signals comprising;
image sensing means including a number of the photoelectric
converting elements, said means being arranged in the path of the
light beam coming through the photo-taking optical system and
producing outputs corresponding to the brightness of the
photographic scene,
time series means for producing a time series of the outputs of the
photoelectric converting elements, said series means being
electrically coupled to the image sensing means and producing a
time series of the outputs of the photoelectric converting elements
by transmitting the outputs of the photoelectric converting
elements one by one,
digital converting means for successively converting the time
series of the outputs of the photoelectric converting elements
produced by means of the time series means into digital values,
said means being electrically coupled to the image sensing
means,
a processing device for determining the exposure value by
processing the outputs converted into digital values by means of
the digital converting means in accordance with a predetermined
estimation function so as to determine the exposure value, said
device being electrically coupled to the digital converting
means.[...]. .Iadd., and
control means for controlling the processing operation of said
processing device, said control means being operable for causing
the processing device to select optional elements whose outputs are
to be utilized for the determination of the exposure value.
.Iaddend.
9. A camera in accordance with claim 8 further comprising;
indication means for indicating the exposure value determined by
the processing device, said means being electrically coupled to the
processing device.
10. A camera in accordance with claim 8, further comprising;
an exposure adjustment device for adjusting the exposure in
accordance with the exposure value determined by means of the
processing device, said device being electrically coupled to the
processing device.
11. A camera in accordance with claim 8, said processing device
comprising;
an addition circuit for summing a plurality of the outputs of the
photoelectrical converting elements converted into digital value,
said circuit being electrically coupled to the digital converting
means,
a division circuit for dividing the value obtained from the
addition circuit by the number of the elements whose outputs have
been summed by the addition circuit, said circuit being
electrically coupled to the addition circuit,
a processing circuit for processing the exposure value in
accordance with the value obtained from the division circuit, said
circuit being electrically coupled to the division circuit.
12. A camera in accordance with claim 8, said processing device
comprising:
a first addition circuit for summing all the outputs of the
photoelectric converting elements converted into digital values,
said circuit being electrically coupled to the digital converting
means,
a first division circuit for dividing the value produced by the
first addition circuit by the total number of the elements, said
circuit being electrically coupled to the first addition
circuit,
a second addition circuit for summing a predetermined number of
outputs of the elements converted into digital values less than the
total number of the outputs of the photoelectric converting
elements converted into digital values, said circuit being
electrically coupled to the digital converting means,
a second division circuit for dividing the value produced by the
second addition circuit by the number of the elements whose outputs
have been summed by the second addition circuit, said circuit being
electrically coupled to the second addition circuit,
selection means for selecting the value produced by the first
division circuit or that produced by the second division circuit,
said selection means being electrically coupled to both of the
division circuits so as to select the value produced by the second
division circuit when the difference between the value produced by
the first division circuit and that produced by the second division
circuit is larger than a predetermined value, and select the value
produced by the first division circuit when the difference is
smaller than the predetermined value,
a processing circuit for processing the exposure value in
accordance with the value selected by the selection means, said
circuit being electrically coupled to the selection means.
13. A camera in accordance with claim 12, further comprising;
switch means for actuating either the first addition and division
circuits or the second addition and division circuits, said switch
means being electrically connected with the first and the second
addition and division circuits.
14. A system comprising;
an image forming optical system, at least a part of said optical
system being movable along an optical axis so as to form an image
of an object at a predetermined position,
photoelectric converting means for converting a light beam into
electrical signals, said converting means being arranged at the
predetermined position and comprising a number of photoelectric
converting elements each producing an electrical output
corresponding to a portion of the light beam,
time series means coupled to the elements for producing a time
series of the outputs of the photoelectric converting elements,
said series means being electrically connected with the
photoelectric converting elements and .[.making.]. .Iadd.forming
.Iaddend.the time series of the outputs of the photoelectric
converting elements by successively transmitting the outputs of the
photoelectric converting elements,
digital converting means coupled to the photoelectric converting
means for successively converting the time series outputs of the
photoelectric converting elements into digital values,
a processing device for processing the outputs of the photoelectric
converting elements converted into digital values by means of the
digital converting means in accordance with a predetermined
estimation function so as to detect the focusing condition of the
image forming optical system, said device being electrically
coupled to the digital converting means so as to produce focusing
information of the optical system by processing the outputs of the
photoelectric converting elements converted into digital values in
accordance with the predetermined estimation function.
15. A system in accordance with claim 14, further comprising:
indication means for indicating the focusing condition of the image
forming optical system on the basis of the focusing information
produced by the processing device.
16. A system according to claim 14, further comprising;
adjusting means for adjusting the image forming optical system in
response to the output of the processing device so that the object
image is formable at the predetermined position, said means being
functionally engaged with the image forming optical system and
electrically coupled to the processing device.
17. A camera comprising:
a photo-taking optical system, at least a part of said system being
movable along an optical axis so as to form an image of the object
to be photographed at a predetermined position,
image sensing means including a number of photoelectric converting
elements arranged on a same plane, said sensing means being
arranged at a position optically equivalent to the predetermined
position and each element in said means producing an electrical
output corresponding to a portion of a light beam coming through
said optical system,
time series means for producing a time series of the outputs of the
photoelectric converting elements, said time series means being
electrically coupled to the image sensing means and producing the
time series of the outputs by successively transmitting the outputs
of the photoelectric converting means,
digital converting means for successively converting the time
series outputs of the photoelectric converting elements, into
digital values, said converting means being electrically coupled to
the image sensing means,
a processing device for processing the outputs of the photoelectric
converting elements converted into digital values by means of
digital converting means in accordance with a predetermined
estimation function so as to detect the focusing condition of the
optical system, said device being electrically coupled to the
digital converting means so as to produce focusing information by
processing the outputs of the photoelectric converting elements
converted into digital values in accordance with the predetermined
estimation function.
18. A camera in accordance with claim 17, further comprising;
indication means coupled to the processing device for indicating
the focusing condition of the photo-taking optical system in
accordance with the focusing information produced by the processing
device.
19. A camera in accordance with claim 17, further comprising;
adjusting means for adjusting the photo-taking optical system in
accordance with the focusing information produced by the processing
device so that the image of the object to be photographed may be
formed at the predetermined position, said adjusting means being
functionally engaged with the movable part of the photo-taking
optical system and electrically connected with the processing
device.
20. A camera in accordance with claim 17, said processing device
comprising;
a processing circuit for producing the absolute values of the
differences between the outputs of pairs of adjacent photoelectric
converting elements converted into digital values, said circuit
being electrically coupled to the digital converting means,
an integrating circuit for successively integrating the values
produced by the processing circuit, said circuit being electrically
coupled to the processing circuit,
a detecting circuit for detecting the maximum value of the value
produced by the integrating circuit during the variation of the
same in accordance with the movement of the movable part of the
photo-taking optical system, said circuit being electrically
coupled to the integrating circuit and producing a focusing signal
when the maximum value of the integrated values is detected.
21. A camera in accordance with claim 20, further comprising;
driving means capable of responsing to the focussing signal
produced by the detecting circuit and of moving the movable part of
the photo-taking optical system along the optical axis, said
driving means being functionally engaged with the movable part of
the photo-taking optical system and electrically coupled to the
detecting circuit so as to move the movable part of the
photo-taking optical system along the optical axis until the
detecting circuit produces the focussing signal.
22. A camera in accordance with claim 20, further comprising;
indication means for indicating the focussing condition relative to
the object to be photographed, of the photo-taking optical system
in accordance with the focussing signal produced by the detecting
circuit, said indication means being electrically connected with
the detecting circuit.
23. A system capable of both exposure measurement and detection of
focusing condition of an image forming optical system settable
along an optical axis to form an image of an object at a
predetermined position, comprising
photoelectric converting means for converting a light beam into
electrical signals, said converting means being arranged at the
predetermined position, and including a number of photoelectric
converting elements producing electric outputs corresponding to the
light beam,
time series producing means coupled to said converting elements for
producing a time series of the outputs of the photoelectric
converting elements by successively transmitting the outputs of the
photoelectric converting elements,
digital converting means for successively converting the time
series outputs of the photoelectric converting elements produced by
the time series means into digital values, said converting means
being electrically connected with the photoelectric converting
means,
a first processing device for processing the outputs of the
photoelectric converting elements converted into digital values in
accordance with a first predetermined estimation function so as to
detect the focusing condition of the optical system, said device
being electrically connected with the digital converting means,
a second processing device for processing the outputs of the
photoelectric converting elements converted into digital values by
means of the digital converting means on the basis of a second
predetermined estimation function, so as to determine an exposure
value, said second processing device being electrically connected
with the digital converting means.
24. A system in accordance with claim 23, further comprising;
indication means coupled to the first processing device for
indicating the focusing condition of the image forming optical
system in acordance with the focus point detection information
produced by the first processing device.
25. A system in accordance with claim 23, further comprising;
indication means for indicating the exposure value determined by
the exposure measurement information produced by the second
processing device, said means being electrically connected with the
second processing device.
26. A system for exposure measurement and focus adjustment of an
image forming optical system settable along an optical axis to form
an image of an object at a predetermined position, comprising
photoelectric converting means for converting a light beam into
electrical signals, said converting means being arranged at the
predetermined position, and including a number of photoelectric
converting elements producing electric outputs corresponding to the
light beam,
time series producing means coupled to said converting elements for
producing a time series of the outputs of the photoelectric
converting elements by successively transmitting the outputs of the
photoelectric converting elements,
digital converting means for successively converting the time
series output of the photoelectric converting elements produced by
the time series means into digital values, said converting means
being electrically connected with the photoelectric converting
means,
a first processing device for processing the outputs of the
photographic converting elements converted into digital values in
accordance with a first predetermined estimation function so as to
detect the focusing condition of the optical system, said device
being electrically connected with the digital converting means,
a second processing device for processing the outputs of the
photoelectric converting elements converted into digital values by
means of the digital converting means on the basis of a second
predetermined estimation function, so as to determine an exposure
value, said second processing device being electrically connected
with the digital converting means, and
adjusting means for adjusting the image forming optical system in
accordance with the output of the first processing device, so that
the image of the object may be formed at the predetermined
position, said means being functionally engaged with the image
forming optical system and electrically connected with the first
processing device.
27. A system for exposure control and detection of focusing
condition of an image forming optical system setting along an
optical axis to form an image of an object at a predetermined
position, comprising
photoelectric converting means for converting a light beam into
electrical signals, said converting means being arranged at the
predetermined position, and including a number of photoelectric
converting elements producing electric outputs corresponding to the
light beam,
time series producing means coupled to said converting elements for
producing a time series of the outputs of the photoelectric
converting elements by successively transmitting the outputs of the
photoelectric converting elements,
digital converting means for successively converting the time
series outputs of the photoelectric converting elements produced by
the time series means into digital values, said converting means
being electrically connected with the photoelectric converting
means,
a first processing device for processing the outputs of the
photoelectric converting elements converted into digital values in
accordance with a first predetermined estimation function so as to
detect the focusing condition of the optical system, said device
being electrically connected with the digital converting means,
a second processing device for processing the outputs of the
photoelectric converting elements converted into digital values by
means of the digital converting means on the basis of a second
predetermined estimation function, so as to determine an exposure
value, said second processing device being electrically connected
with the digital converting means, and
exposure adjusting means for adjusting the exposure value on the
basis of the exposure measurement information produced by the
second processing device, said means being electrically connected
with the second processing devices.
28. A camera capable of both exposure measurement and focus point
detection of a photo-taking optical system settable along an
optical axis so as to form an image of an object at a predetermined
position comprising;
image sensing means having a number of photoelectric converting
elements arranged a same plane, said sensing means being arranged
at a position optically equivalent to the predetermined position
and each element in said means producing an electrical output
corresponding to a portion of a light beam coming through the
optical system from the object,
time series means for producing a time series of the outputs of the
photoelectric converting elements said means being electrically
connected with the image sensing means and producing the time
series of the photoelectric converting elements by successively
delivering the outputs of the photoelectric converting
elements,
digital converting means for successively converting the time
series outputs of the photoelectric converting elements produced by
the time series means into digital values, said means being
electrically connected with the image sensing means,
a first processing device for processing the outputs of the
photoelectric converting elements converted into digital values by
means of the digital converting means, in accordance with a first
predetermined estimation function, so as to detect the focusing
condition of the optical system, said device being electrically
connected with the digital converting means and producing focusing
detection information of the optical system by processing the
outputs of the elements converted into digital values in accordance
with the first estimation function,
a second processing device for processing the outputs of the
photoelectric converting elements converted into digital values by
means of the digital converting means in accordance with a second
predetermined estimation function, so as to determine the exposure
value, said device being electrically connected with the digital
converting means and producing the exposure measurement information
by processing the outputs of the elements converted into digital
values in accordance with the second estimation function.
29. A camera in accordance with claim 28, said first processing
device comprising;
a processing circuit for producing the absolute values of the
differences between the outputs of pairs of adjacent photoelectric
converting elements converted into digital values, said circuit
being electrically coupled to the digital converting means,
an integrating circuit for successively integrating the values
produced by the processing circuit, said circuit being electrically
coupled to the processing circuit,
a detecting circuit for detecting the maximum value of the value
produced by the integrating circuit during the variation of the
same in accordance with the movement of the movable part of the
photo-taking optical system, said circuit being electrically
coupled to the integrating circuit and producing a focusing signal
when the maximum value of the integrated value is detected.
30. A camera in accordance with claim 29, further comprising;
driving means capable of responsing to the focussing signal
produced by the detection circuit and of moving the movable part of
the optical system along the optical axis, said means being
functionally engaged with the movable part of the optical system
and electrically connected with the detecting circuit, so as to
move the movable part of the optical system along the optical axis
until the detecting circuit produces the focussing signal.
31. A camera in accordance with claim 29, further comprising;
indication means for indicating the focussing condition relative to
the object to be photographed, of the optical system in accordance
with the focussing signal produced by the detecting circuit, said
means being electrically connected with the detecting circuit.
32. A camera in accordance with claim 28, said second processing
device comprising:
an addition circuit for successively adding the outputs of the
photoelectric converting elements converted into digital values,
said circuit being electrically connected with the digital
converting means,
a dividing circuit for dividing the values obtained from the
addition circuit by the total number of the photoelectric
converting elements, said dividing circuit being electrically
connected with the addition circuit,
a processing circuit for processing the exposure value in
accordance with the value obtained from the dividing circuit.
33. A camera in accordance with claim 32, further comprising;
indication means for indicating the exposure value on the bases of
the value obtained from the processing circuit, said indication
means being electrically connected with the processing circuit.
34. A camera in accordance with claim 32, further comprising;
exposure adjusting means for adjusting the exposure on the basis of
the value obtained from the processing circuit, said adjusting
means being electrically connected with the processing circuit.
35. A system capable of .[.either.]. exposure measurement .[.or
the.]. .Iadd.and .Iaddend.detection of focusing condition of an
optical system comprising;
a plurality of photoelectric converting elements for converting
light beam into electrical signals, each photoelectric converting
element producing an electrical output corresponding to a portion
of the light beam,
.[.sequential sensing.]. .Iadd.time series output .Iaddend.means
for successively transmitting the outputs of successive ones of the
photoelectric converting elements, said .[.sensing.]. .Iadd.time
series output .Iaddend.means being electrically connected with the
photoelectric converting elements,
digital converting means for converting the outputs successively
transmitted by means of the .[.sensing.]. .Iadd.time series output
.Iaddend.means, of the photoelectric converting elements into
digital values,
a processing device for processing the outputs of the photoelectric
converting elements converted in digital values by means of the
digital converting means .[.either.]. in accordance with a first
predetermined estimation function so as to determine a exposure
value, .[.or.]. .Iadd.and .Iaddend.in accordance with the
predetermined second estimation function so as to detect the
focusing condition of the optical system, said device being
electrically connected with the digital converting means in such a
manner that .[.either.]. exposure measurement information .[.or.].
.Iadd.and .Iaddend.focusing condition information .[.is.].
.Iadd.are .Iaddend.produced by processing the outputs of the
photoelectric converting elements converted into digital value in
accordance with .[.either of.]. the estimation functions
.Iadd.control means for controlling the processing device to
operate for either focus detection or exposure
measurement.Iaddend..
36. A system capable of either exposure measurement or detection of
focusing condition of an image forming optical system at least one
part of which is movable along an optical axis so as to form an
image of an object at a predetermined position, comprising
photoelectric converting means for converting light beam into
electrical signals, said means being arranged at the predetermined
position and including
a plurality of photoelectric converting elements, each element
producing an output corresponding to a portion of the input light
beam,
time series means for making a time series of the outputs of the
photoelectric converting elements, said means being electrically
connected with the photoelectric means, so as to make the time
series of the outputs of the photoelectric converting elements by
successively delivering the outputs of the elements one by one,
digital converting means for successively converting the time
series outputs, of the photoelectric elements into digital values,
said means being electrically connected with an output terminal of
the photoelectric converting means,
a processing device for processing the outputs of the photoelectric
converting elements converted in digital values by means of the
digital converting means either in accordance with a first
predetermined estimation function, so as to determine the exposure
value or in accordance with a second predetermined estimation
function, so as to detect the focusing condition of the optical
system, said device being electrically connected with the digital
converting means in such a manner that either the exposure
measurement information or information relating with the focusing
condition is produced by processing the outputs of the
photoelectric converting elements converted into digital values, of
the photoelectric converting elements in accordance with either of
the estimation functions.[...]..Iadd., and control means for
controlling said processing device, said control means causing the
processing device to operate for either the focus detection or
exposure measurement. .Iaddend.
37. A camera capable of .[.either.]. exposure measurement .].or.].
.Iadd.and .Iaddend.detection of focusing condition of image forming
optical system by converting the light beam into electrical signal
comprising:
image sensing means including a plurality of photoelectric
converting elements arranged on the same plane, said means being
arranged at a position, at which light coming through the optical
system can be caught, each photoelectric converting elements
producing an output corresponding to a portion of the light,
time series means for successively delivering the outputs of the
photoelectric converting elements, said means being electrically
connected with the image sensing means,
digital converting means for successively converting the outputs
successively delivered by means of the time series means, of the
photoelectric converting elements into digital values, said means
being electrically connected with an output terminal of the image
sensing means,
a processing device for processing the outputs converted in digital
value by means of the digital converting means, of the
photoelectric converting elements .[.either.]. in accordance with a
first predetermined estimation function, so as to determine the
exposure value .[.or.]. .Iadd.and .Iaddend.in accordance with a
second predetermined estimation function, so as to detect the
focusing condition of the optical system, said device being
electrically connected with the digital converting means, receiving
the outputs converted into digital values, of the photoelectric
converting elements and producing .[.either.]. exposure measurement
information .[.or the estimation functions .Iadd.and
.Iaddend.information relating with the focusing condition of the
photographic optical system by processing the outputs in accordance
with .[.either of.]. the estimation functions .Iadd.and control
means for controlling the processing device to operate for either
focus detection or exposure measurement.Iaddend..
38. For a camera capable of exposure measurement in an optional
zone of a photographic scene and having means for setting one or
more other exposure factors; an exposure regulating arrangement,
comprising;
image sensing means including a plurality of photoelectric
converting elements regularly arranged on a same plane, said
sensing means being arranged at a position in the path of a light
beam from the photograhic scene, each of said converting elements
producing an electrical signal corresponding to a portion of the
light beam,
time series means for making a time series of the outputs of said
photoelectric converting elements, said time series means being
electrically connected with said image sensing means so as to make
a time series of the outputs of the converting elements by
successively delivering the outputs of the converting elements in
accordance with the order of the arrangement of the converting
elements,
brightness determining means for detecting the brightness of the
photographic scene on the basis of the outputs of the photoelectric
converting elements, said brightness detecting means being
electrically connected with the image sensing means and detecting
the brightness of the photographic scene by processing at most all
the outputs of the photoelectric converting elements.Iadd., control
means for controlling the detecting operation of said brightness
determining means, said control means being operable for causing
the brightness determining means to select optional elements whose
outputs are to be processed for brightness detection, .Iaddend.and
exposure determining means for determining an exposure value on the
basis of the output of said brightness detecting means and one or
more of the other preset exposure factors, said exposure
determining means being electrically connected with the brightness
detecting means. .Iadd. 39. In a device comprising:
sensing means including a plurality of sensing elements, each
providing an electrical signal corresponding to radiation energy
incident thereon, said sensing means being arranged to receive an
image to provide an electrical output corresponding to the
radiation energy distribution of the image thereon; and
a circuit system responsive to the electrical output of said
sensing means to provide an output signal indicative of sharpness
of the image on the sensing means;
time seriation output means for causing said sensing means to
provide as the output thereof the electrical signals of the
respective sensing elements in a time-seriated manner;
wherein said circuit system includes:
first circuit means for receiving the time-seriated output of said
sensing means to detect, in a time-seriated manner, variations in
the radiation energies between close positions in the image and for
providing output signals indicating said variations in a
time-seriated manner; and
second circuit means receiving the time-seriated output signals of
said first circuit menas to detect the sharpness of the image on
said sensing means, said second circuit means providing said output
signal indicative of the image sharpness on the basis of the
time-seriated output signals of the first circuit means and being
arranged to provide said output signal indicative of the image
sharpness by integrating said variations in the radiation energies
on the basis of the time-seriated output signals of said first
circuit means..Iaddend..Iadd. 40. The device according to claim 39,
wherein said time seriation output means is pulse controlled means
which is operable, in response to supplied control pulses, to feed
the electrical signal of each of the sensing elements in said
sensing means to said circuit system in a time-seriated
manner..Iaddend..Iadd. 41. The device according to claim 40,
wherein said sensing means includes an array of a plurality of
addressable sensing elements, and said time seriation output means
is address means for addressing, in response to the supplied
control pulses and in a time-seriated manner, the respective
sensing elements in said sensing means to feed the electrical
signal of each of the sensing elements in the sensing means to said
circuit system in a time-seriated manner. .Iaddend. .Iadd. 42. The
device according to claim 39, wherein said first circuit means
includes:
delay means receiving the time-seriated output of said sensing
means and delaying the same for a predetermined time; and
detecting means receiving the time-seriated output of the sensing
means and the delayed output provided by said delay means and
detecting the variation in the radiation energies between each of
two close positions in the image on the basis of the and delayed
outputs of said sensing means and said delay means, said detecting
means providing absolute value signals indicating said variations
in a time-seriated manner;
and said second circuit means includes;
integration means receiving the time-seriated absolute value
signals provided by said detecting means in said first circuit
means and integrating the absolute value signals to provide said
output signal indicative of the image sharpness. .Iaddend..Iadd.
43. A device for detecting sharpness of an image formed by an image
forming optical system, comprising:
(A) scanning type image sensing means having a plurality of sensing
elements, each providing an electrical signal corresponding to
radiation energy incident thereon, said sensing means being
arranged to receive the image formed by said optical system to
provide a time-seriated scanned image signal corresponding to the
radiation energy distribution of the image thereon; and
(B) a circuit system receiving the time-seriated scanned image
signal provided by said sensing means to detect the sharpness of
the image on the sensing means, said circuit system including:
(B-1) first circuit means receiving said scanned image signal to
detect, in a time-seriated manner, variations in the radiation
energies between close positions in the image, said first circuit
means providing output signals indicating said variations in a
time-seriated manner; and .Iadd.
(B-2) second circuit means receiving the time-seriated output
signals of said first circuit means to detect the sharpness by
integrating said variations in the radiation energies of the image
on said sensing means, said second circuit means providing an
electrical output indicative of the image sharpness on the basis of
said time-seriated output signals of the first circuit means.
.Iaddend..Iadd. 44. A device according to claim 43, wherein said
scanning type image sensing means includes time seriation output
means to provide as an output of the sensing means the electrical
signals of the respective sensing elements in a time-seriated
manner. .Iaddend..Iadd. 45. A device according to claim 44, wherein
said time seriation output means is pulse controlled means which is
operable, in response to supplied control pulses, to feed the
electrical signal of each of the sensing elements to said circuit
system in the time-seriated manner. .Iaddend..Iadd. 46. A device
according to claim 45, wherein said sensing means has an array of a
plurality of addressable sensing elements, and said time seriation
output means is address means for addressing, in response to the
supplied control pulses and in a time-seriated manner, the
respective sensing elements to feed the electrical signal of each
of the sensing elements to said circuit system in a time-seriated
manner. .Iaddend..Iadd. 47. A device according to claim 43, wherein
said first circuit means in said circuit system is so arranged as
to detect, in a time-seriated manner, the variations in the
radiation energies between each of two close positions in the
image, and said second circuit means in said circuit system is so
arranged as to provide said electrical output indicative of the
image sharpness by integrating said variations in the radiation
energies on the basis of the time-seriated output signals of said
first circuit means. .Iaddend..Iadd. 48. A device according to
claim 47, wherein said first circuit means includes:
delay means receiving the time-seriated scanned image signal
provided by said sensing means and delaying the same for a
predetermined time; and
detecting means receiving the time-seriated scanned image signal
provided by the sensing means and the delayed output provided by
said delay means and detecting the variation in the radiation
energies between each of the two close positions in the image on
the basis of the and delayed image signals of said sensing means
and said delay means, said detecting means providing absolute value
signals indicating said variations in a time-seriated manner;
and said second circuit means includes:
integtration means receiving the time-seriated absolute value
signals provided by said detecting means in said first circuit
means and integrating the absolute value signals to provide said
electrical output indicative of the image sharpness. .Iaddend.
.Iadd. 49. A device for detecting sharpness of an image formed by
an image forming optical system, comprising:
sensing means including a plurality of sensing elements, each
providing an electrical signal corresponding to radiation energy
incident thereon, said sensing means being arranged to receive the
image formed by said optical system to provide an electrical output
corresponding to radiation energy distribution of the image
thereon;
a circuit system receiving the electrical output of said sensing
means to detect the sharpness of the image on the sensing means,
said circuit system including:
first circuit means receiving the electrical output of the sensing
means to detect variations in the radiation energies between close
positions in the image, said first circuit means providing output
signals indicating said variations; and
second circuit means receiving output signals of said first circuit
means to detect the sharpness of the image on said sensing means,
said second circuit means providing an output signal indicative of
the image sharpness by integrating said variations in the radiation
energies on the basis of the output signals of the first circuit
means; and
time seriation output means for causing said sensing means to
provide as the output thereof the electrical signals of the
respective sensing elements in a time-seriated manner. .Iaddend.
.Iadd. 50. The device according to claim 49, wherein said time
seriation output means is pulse controlled means which is operable,
in response to supplied control pulses, to feed the electrical
signal of each of the sensing elements in said sensing means to
said circuit system in a time-seriated manner. .Iaddend..Iadd. 51.
The device according to claim 50, wherein said sensing means
includes an array of a plurality of addressable sensing elements,
and said time seriation output means is address means for
addressing, in response to the supplied control pulses and in a
time-seriated manner, the respective sensing elements in said
sensing means to feed the electrical signal of each of the sensing
elements in the sensing means to said circuit system in a
time-seriated manner. .Iaddend..Iadd. 52. The device according to
claim 49, wherein said first circuit means in said circuit system
is so arranged as to receive the time-seriated output of said
sensing means to detect, in a time-seriated manner, the variations
in the radiation energies between the close positions in the image,
said first circuit means providing output signals indicating said
variations in a time-seriated manner; and second circuit means in
said circuit system is so arranged as to receive the time-seriated
output signals of said first circuit means to detect the sharpness
of the image on said sensing means, said second circuit means
providing said output signal indicative of the image sharpness on
the basis of the time-seriated output signals of the first circuit
means. .Iaddend. .Iadd. 53. The device according to claim 52,
wherein said second circuit means is so arranged as to provide said
output signal indicative of the image sharpness by integrating said
variations in the radiation energies on the basis of the
time-seriated output signals of said first circuit means.
.Iaddend..Iadd. 54. The device according to claim 53, wherein said
first circuit means includes:
delay means receiving the time-seriated output of said sensing
means and delaying the same for a predetermined time; and
detecting means receiving the time-seriated output of the sensing
means and the delayed output provided by said delay means and
detecting the variation in the radiation energies between each of
two close positions in the image on the basis of the and delayed
outputs of said sensing means and said delay means, said detecting
means providing absolute value signals indicating said variations
in a time-seriated manner;
and said second circuit means includes:
integration means receiving the time-seriated absolute value
signals provided by said detecting means in said first circuit
means and integrating the absolute value signals to provide said
output signal indicative of the image sharpness. .Iaddend..Iadd.
55. A device for detecting a focus of an image forming optical
system which is adjustable along an optical axis thereof, onto an
object, comprising:
(A) scanning type image sensing means having a plurality of sensing
elements, each providing an electrical signal corresponding to
radiation energy incident thereon, said sensing means being
arranged to receive an image of the object formed by the optical
system to provide a time-seriated scanned image signal
corresponding to the radiation energy distribution of the image
thereon; and
(B) a circuit system receiving the time-seriated scanned image
signal provided by said sensing means to detect the focus of said
optical system onto the object, said circuit system including:
(B-1) first circuit means receiving said scanned image signal to
detect, in a time-seriated manner, variations in the radiation
energies between close positions in the image, said first circuit
means providing output signals indicating said variations in a
time-seriated manner;
(B-2) second circuit means receiving the time-seriated output
signals of said first circuit means to detect the sharpness of the
image, said second circuit providing an electrical output by
integrating said variations in the radiation energies on the basis
of the output signals of the first circuit means, said electrical
output having a characteristic by accumulating correlation
information on the basis of the output signals of said correlation
detecting means when the optical system is properly focused onto
the object; and
(B-3) third circuit means for detecting whether the output of said
second circuit means has the characteristic as the optical system
is adjusted along the optical axis. .Iaddend..Iadd. 56. A device
according to claim 55, wherein said scanning type image sensing
means includes time seriation output means to provide as an output
of the sensing means the electrical signals of the respective
sensing elements in a time-seriated manner. .Iaddend. .Iadd. 57. A
device according to claim 56, wherein said time seriation output
means is pulse controlled means which is operable, in response to
supplied control pulses, to feed the electrical signal of each of
the sensing elements to said circuit system in a time-seriated
manner. .Iaddend..Iadd. 58. A device according to claim 57, wherein
said sensing means has an array of a plurality of addressable
sensing elements, and said time seriation output means is address
means for addressing, in response to the supplied control pulses
and in a time-seriated manner, the respective sensing elements to
feed the electrical signal of each of the sensing elements to said
circuit system in a time-seriated manner. .Iaddend..Iadd. 59. A
device according to claim 55, wherein said first circuit means in
said circuit system is so arranged as to detect, in a time-seriated
manner, the variations in the radiation energies between each of
two close positions in the image, and said second circuit means in
said circuit system is so arranged as to provide an electrical
output indicative of the image sharpness by integrating said
variations in the radiation energies on the basis of the
time-seriated output signals of said first circuit means.
.Iaddend..Iadd. 60. A device according to claim 59, wherein said
sensing means is so arranged as to receive the image of the object
formed by the optical system at a position corresponding to a
predetermined focal plane of the optical system so that said
characteristic output of the second circuit means indicates the
maximum image sharpness on said predetermined focal plane.
.Iaddend. .Iadd. 61. A device according to claim 60, wherein said
second circuit means is so arranged as to provide a maximum output
as said characteristic output when the image sharpness on said
predetermined focal plane reaches maximum, and said third circuit
means is so arranged as to detect whether the output of said second
circuit means reaches maximum as the optical system is adjusted
along the optical axis. .Iaddend..Iadd. 62. A device according to
claim 61, wherein said first circuit means includes:
delay means receiving the time-seriated scanned image signal
provided by said sensing means and delaying the same for a
predetermined time; and
detecting means receiving the time-seriated scanned image signal
provided by the sensing means and the delayed output provided by
said delay means and detecting the variation in the radiation
energies between each of the two close positions in the image on
the basis of the and delayed image signals of said sensing means
and said delay means, said detecting means providing absolute value
signals indicating said variations in a time-seriated manner;
and said second conduit means includes:
integration means receiving the time-seriated absolute value
signals provided by said detecting means in said first circuit
means and integrating the absolute value signals to provide said
electrical output indicative of the image sharpness.
.Iaddend..Iadd. 63. A system for detecting sharpness of an image
formed by an image forming optical system, comprising:
(A) scanning type image sensing means having a plurality of sensing
elements, each for receiving a different image portion of said
image and for providing an electrical signal corresponding to said
image portion, said sensing means being arranged to receive the
image formed by the optical system to provide as an output
indicative of imaging condition of the image the electrical signals
of the respective elements in a time-seriated manner;
(B) means for detecting, on the basis of the output of said sensing
means, correlation between each of two close image portions of the
image in a time-seriated manner, said correlation detecting means
providing a time-seriated electrical output indicative of the
correlation; and
(C) means receiving the output of said correlation detecting means
and providing a resultant output indicative of the sharpness of the
image
formed by the optical system in a digital word. .Iaddend..Iadd. 64.
In a focusing system, a focus detecting device comprising:
(A) sensing means having a plurality of radiation sensitive
elements, each providing an electrical signal corresponding to
radiation incident thereon, said sensing means being disposed at a
position corresponding to at least near a predetermined focal plane
on which an image of an object is to be focused, so as to receive
radiation distribution which changes with the change in the
focusing condition of the focusing system;
(B) means for causing said sensing means to provide as an output
indicative of said radiation distribution the electrical signals of
the respective elements in a time seriated manner;
(C) means for detecting, on the basis of the output of said sensing
means, correlation of radiation distribution between each of two
close positions in said focal plane, said correlation detecting
means providing electrical signals indicative of the correlations;
and
(D) means receiving the electrical signals from said correlation
detecting means and providing a resultant output indicative of the
focusing
condition of the focusing system. .Iaddend..Iadd. 65. A focus
detecting device according to claim 64, wherein said correlation
detecting means provides each electrical signal indicative of each
correlation in a digital word. .Iaddend..Iadd. 66. A focus
detecting device according to claim 65, wherein said correlation
detecting means provides the electrical signals in a time-seriated
manner. .Iaddend..Iadd. 67. A focus detecting device according to
one of claims 64 to 66, wherein said resultant output providing
means provides the resultant output in a digital word.
.Iaddend..Iadd. 68. An exposure measurement system comprising:
(A) light sensing means including a plurality of sensing elements,
each for receiving a portion of a light and for providing an
electrical signal corresponding to said portion of the light;
(B) time seriation means for causing said sensing means to provide
as an output thereof the electrical signals of the respective
sensing elements in a time-seriated manner; and
(C) processing means receiving the time-seriated output of said
sensing means and processing at most all the electrical signals of
said sensing elements to determine an exposure value; and
(D) control means for controlling the signal processing operation
of said processing means, said control means being operable for
causing the processing means to select optional elements whose
electrical signals are to be processed for the determination of the
exposure value.
.Iaddend..Iadd. 69. An exposure measurement system according to
claim 68, wherein said processing means determines the exposure
value on the basis of the output of said sensing means and one or
more other exposure factors. .Iaddend..Iadd. 70. An exposure
measurement system according to claims 68 or 69, wherein said
processing means provides a resultant output indicative of the
determined exposure value in a digital word. .Iaddend..Iadd. 71. A
system for exposure measurement and detection of focusing condition
of an image forming optical system onto an object, comprising:
(A) sensing means including a plurality of sensing elements, each
providing an electrical signal corresponding to a portion of a
light incident thereon, said sensing means being arranged to
receive an image of the object formed by said optical system;
(B) time seriation means for causing said sensing means to provide
as an output thereof the electrical signals of the respective
sensing elements in a time-seriated manner;
(C) first processing means receiving the time-seriated output of
said sensing means and processing said output to detect the
focusing condition of the optical system onto the object;
(D) second processing means receiving the time-seriated output of
said sensing means and processing said output to determine an
exposure value; and
(E) sequence control means for controlling operations of said time
seriation means and said first and second processing means, said
sequence control means firstly causing said time seriation means
and one of said first and second processing means to operate for
one of said focus detection and exposure determination and after
the termination of said one of focus detection and exposure
determination causing the time seriation means and the other of
said first and second processing means to operate for the other of
said focus detection and exposure determination. .Iadd.
. A system according to claim 71, wherein said sequence control
means firstly causes said first processing means to operate for the
focus detection and after the termination of the focus detection by
the first processing means causes said second processing device to
operate for the exposure determination. .Iaddend. .Iadd. 73. A
system according to claim 71, wherein said first processing means
provides a resultant output indicative of the focusing condition of
the optical system in a digital word. .Iaddend..Iadd. 74. A system
according to claim 71 or 73, wherein said processing means provides
a resultant output indicative of the determined exposure value in a
digital word. .Iaddend..Iadd. 75. A system for exposure measurement
and detection of focusing condition of an image forming optical
system onto an object, comprising:
(A) sensing means including a plurality of sensing elements, each
providing an electrical signal corresponding to a portion of a
light incident thereon, said sensing means being arranged to
receive an image of the object formed by said optical system;
(B) time seriation means for causing said sensing means to provide
an output thereof the electrical signals of the respective sensing
elements in a time-seriated manner;
(C) processing means receiving the output of said sensing means and
processing said output for focus detection and for exposure
determination, said processing means being selectively operable in
a first operation mode for detection of the focusing condition of
the optical system on the basis of said output and in a second
operation mode for determining an exposure value on the basis of
said output; and
(D) sequence control means for controlling operations of said time
seriation means and said processing means, said sequence control
means firstly causing the time seriation means to operate and the
processing means to operate in one of said first and second
operation modes for one of said focus detection and exposure
determination and after the termination of said one of the focus
detection and exposure determination causing again the time
seriation means to operate and the processing means to operate in
the other of said first and second operation modes for the other of
said focus detection and exposure determination.
.Iaddend..Iadd.
6. A system according to claim 75, wherein said sequence control
means firstly causes said processing means to operate in said first
operation mode for the focus detection and after the termination of
the focus detection causes the processing means to operate in said
second operation mode for the exposure determination.
.Iaddend..Iadd. 77. A system according to claim 75 or 76, wherein
said processing means provides a first output indicative of the
focusing condition of the optical system and a second output
indicative of the determined exposure value in digital words.
.Iaddend..Iadd. 78. A system capable of either of exposure
measurement or detection of focusing condition of an image forming
optical system onto an object, comprising:
(A) sensing means including a plurality of sensing elements, each
providing an electrical signal corresponding to a portion of a
light incident thereon, said sensing means being arranged to
receive an image of the object formed by said optical system;
(B) time seriation means for causing said sensing means to provide
as an output thereof the electrical signals of the respective
sensing elements in a time-seriated manner;
(C) processing means receiving the output of said sensing means and
processing said output for either of detecting focusing condition
of the optical system or determining an exposure value, said
processing means providing focusing condition information or
exposure value information on the basis of the output of the
sensing means; and
(D) control means for controlling said time seriation means and
said processing means, said control means causing the time
seriation means and the processing means to operate for either of
the focus detection or
exposure determination. .Iaddend..Iadd. 79. A system according to
claim 78, wherein said processing means provides said focusing
condition information or exposure value information in a digital
word. .Iaddend. .Iadd. 80. In a focusing system, a focus detecting
device comprising:
(A) sensing means having a plurality of radiation sensitive
elements, each providing an electrical signal corresponding to
radiation incident thereon, said sensing means being disposed at a
position corresponding to at least near a predetermined focal plane
on which an image of an object is to be focused, so as to receive
radiation distribution which changes with the change in the
focusing condition of the focusing system;
(B) means for causing said sensing means to provide as an output
indicative of said radiation distribution the electrical signals of
the respective elements in a time seriated manner;
(C) means for detecting, on the basis of the output of said sensing
means, correlation of radiation distribution between each of two
close positions in said focal plane, said correlation detecting
means providing electrical signals indicative of the correlation;
and
(D) means receiving the electrical signal from said correlation
detecting means and providing a resulting output indicative of the
focusing condition of the focusing system by accumulating
correlation information on the basis of the output signals of said
correlation detecting means. .Iaddend.
Description
BACKGROUND OF THE INVENTION
Field of the Invention
The present invention relates to a system for exposure measurement
for the optical instrument such as camera and/or focus detection
for the image forming optics.
2. Description of the Prior Art
Among the conventional exposure measurement system for optical
instrument such as camera in which the light measuring method
suited for the photographic field at the time of taking photograph
can be chosen there is one which is so constructed that a plural
number of light sensing elements such as CdS cells intended for the
spot light measurement and another plural number of light sensing
elements such as CdS cells intended for the mean light measurement
are provided at the positions different from each other whereby at
taking photograph either the spot light measurement or the mean
light measurement is selected in accordance with the conditions of
the photographic field at taking photograph by comparing the output
of the one, light measuring method with that of the other light
measuringmethod so as to carry out the suitable exposure
measurement.
One of the example is the camera disclosed in U.S. Pat. No.
3,690,241, in which camera the first light sensing element is
disposed so as to be brought in front of the film while the second
light sensing element is disposed so as to be opposed to the plane
of the pentagonal prism composing a view finder optics of the
camera through which plane the light beam goes out of the
pentagonal prism whereby the first light sensing element serves as
that for the so called spot light measurement responsing to a
comparatively small part of the light beam to be exposed to the
film while the second light sensing element serves as that for the
so called mean light measurement responsing to almost all the light
beam coming from the photographic field. Hereby the first and the
second light sensing element can be connected with the same
exposure measurement circuit selectively by means of the manual
operation from outside of the camera. Therefore it is possible for
a photographer to select either the spot light measurement or the
mean light measurement in accordance with the then condition of the
photographic field so as to carry out a suitable exposure
measurement by selectively connecting the first or the second light
sensing element to the exposure measuring circuit and comparing the
output of the one light measuring method with that of the other
light measuring method for example by means of meter.
However, in case of the exposure measuring system constructed as
mentioned above, the light sensing element for the spot light
measurement is disposed at a certain determined position with
regard to the image plane so that it is disadvantageous that the
light beam only at a certain determined point of the object in the
image plane could be measured, whereby for example in case of the
single reflex camera there is a restriction that the range capable
of the spot light measurement is determined in advance because the
spot light measurement can not be carried out at any optical
position in the object, of the image plane in the view finder.
On the other hand, various methods respectively devices for
detecting the focus point of the image forming optics by utilizing
the photoelectric characteristics of the photoelectric converting
elements have so far been proposed, whereby what is theoretically
considered to be able to obtain the focus point with comparatively
high accuracy is the method as proposed by the Japanese Patent
Publication No. Sho 42-14096 according to which a plural number of
the parts having a fine but proper area are provided on the focus
plane so as to obtain the electrical output by converting the light
amount of each fine part by means of the photoelectric converting
element in such a manner that the differences of the electrical
outputs between two adjacent fine parts are converted in absolute
values or squared value and then added whereby the focus point is
considered to be obtained when the added value is maximum.
However, in case of the device disclosed in the Japanese Patent
Publication No. Sho 42-14096 the analog amount of the output of
each photoelectric converting element is processed and therefore
the composition of the signal processing circuit for processing the
output of each photoelectric converting element is much complicated
so that the exact detection is practically impossible due to the
errors taking place at processing the output signals, which is
disadvantageous. Hereby further the composition of the circuit is
much more complicated according as the number of the photoelectric
converting elements increases so that the number of the elements to
be used is necessarily restricted.
Further, as is disclosed for example, in the Japanese Utility Model
Publication No. Sho 48-43379, a device in which a light sensing
means consisting of a plural number of fine light sensing elements
is used for the focus point detection and the exposure measurement
is so far known whereby in case of the device disclosed in the
Japanese Utility Model No. Sho 48-43379, a method according to
analog control is adopted according to which method the analog
amount of the output of each light sensing element in the light
sensing member is processed so as to control the focus point
detecting and exposure measuring device. However, in the analog
control there is a theoretical instability in such a manner that in
case one light sensing means is used for the focus detection and
the exposure measurement the composition of the electrical circuit
becomes complicated, whereby the error becomes larger at the time
of the focus point detection and of the exposure measurement so
that the exact measurement is practically impossible. Further, in
case the light sensing system is composed of a plural number of the
light sensing elements, the composition of the circuit becomes much
more complicated according as the number of the light sensing
elements increases so that the number of the light sensing elements
is necessarily limited, which makes the exact measurement all the
more difficult.
SUMMARY OF THE INVENTION
A purpose of the present invention is to offer a new system for the
exposure measurement and/or for focus point detection of the image
forming optics according to which system all of the above mentioned
shortcomings of the conventional exposure measurement system, the
conventional focus point detection system and the system in which
one light sensing means is used for the exposure measurement and
the focus point detection can be eliminated.
Further another purpose of the present invention is to offer a new
system for the exposure measurement and/or for focus point
detection of the image forming optics according to which system all
of the above mentioned shortcomings of the conventional exposure
measurement system, the conventional focus point detection system
and the system in which one light sensing means is used for the
exposure measurement and the focus point detection can be
eliminated, by scanning purely electrically the image pattern of
the object by means of the image senser consisting of a plural
number of the disposed respectively integrated fine light sensing
elements and converting the then obtained output of the light
sensing elements.
Further another purpose of the present invention is to offer a new
exposure measurement system capable of automatically selecting a
light measurement method suited for the condition of the
photographic field.
Further another purpose of the present invention is to offer is to
compose the exposure measurement system in such a manner that by
means of the image senser any optional fine part of the brightness
in the total image plane of the photographic field can be
selectively measured.
Further another purpose of the present invention is to compose the
exposure measurement system in such a manner that by means of the
image senser the spot light measurement can be carried out on any
optional fine part of the brightness in the total image plane of
the photograhic field, while the mean light measurement can be
carried out for the total image plane of the photographic field so
that either of the light measuring system can be selected
automatically by means of the output of both of the above light
measuring systems.
Further another purpose of the present invention is to compose the
exposure measurement system in such a manner that by scanning the
image pattern of the object by means of the light sensing means
disposed so as to receive the light beam coming from the object to
be photographed and presenting a plural number of the fine light
sensing elements consisting of the image senser such as photodiode
array (MOS image senser), CCD (charge coupled devices) and so on an
output is produced in each fine light sensing element of the light
sensing means so as to correspond to the position of the object to
be photographed and by selectively taking out the output a desired
spot light measurement can be carried out for the object to be
photographed.
Further another purpose of the present invention is to offer a new
focus point detecting system which is so constructed that at the
image forming position of the image forming optics or at the
position equivalent to the image forming position an image senser
consisting of a plural number of the fine disposed respectively
integrated light sensing elements is arranged and the outputs of
the light sensing elements in the image senser are converted into
digital values one after another in accordance with the arranged
order while the absolute values of the differences between the
digital values of the outputs between the adjacent light sensing
elements are summarized one after another whereby the focus point
is considered to be obtained when the total sum of the absolute
values of the differences between the digital values becomes
largest during the adjustment of the image forming optics.
Further another purpose of the present invention is to compose a
camera capable of automatically adjusting the focussing of the
photographic optics, by applying in the actual camera a focus point
detecting system so constructed that by means of an image senser
presenting a plural number of the fine light sensing elements the
image pattern of the object formed by the optics is purely
electrically scanned and the then obtained scanning signals are
converted into digital values one after another while the absolute
values of the differences between the digital values of the
adjacent light sensing elements are summarized one after another
whereby the focus point of the optics is detected by detecting the
variation of the summarized value during the adjustment of the
optics.
Further another purpose of the present invention is to offer a new
system for the exposure measurement and for the focus point
detection by means of one common light sensing means which system
is so constructed that the combined focus signal as well as the
exposure signal are obtained by scanning the image of the object by
means of an image senser consisting of a plural number of the fine
disposed respectively integrated light sensing elements and by
converting each of the then obtained output of each light sensing
element into digital value one after another.
Further other purpose of the present invention will be disclosed in
the following explanation to be made for the embodiments of the
present invention in accordance with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows an embodiment of the arrangement of light sensing
elements suited for the exposure measuring system according to the
present invention.
FIG. 2 shows a block circuit diagram of an embodiment of the
exposure measuring system using the image senser IS as is shown in
FIG. 1 in accordance with the present invention applied for a
general camera.
FIG. 3(a) shows an electrical circuit diagram of the electrical
connection among the photo diode array, the analog switch 1 and the
shift register 2 in case in the embodiment shown in FIG. 2 the
photo diode array (MOS image senser) is adopted as image senser
IS.
FIG. 3(b) shows the timing chart for showing the signal outputs
taken out of the photo diodes one after another in the electrical
circuit shown in FIG. 3(a).
FIG. 4 shows important parts of a camera in which such an exposure
measuring system as is shown in FIG. 2 is built in.
FIG. 5(a) shows an embodiment of the arrangement of the light
sensing elements of the image senser suited for the focus detecting
system according to the present invention.
FIG. 5(b) shows a part of the image senser IS' shown in FIG. 5(a)
in enlargement.
FIG. 6(a) shows a principal arrangement of the important parts in
case the focus detecting system according to the present invention
is applied for an ordinary camera.
FIG. 6(b) shows the relation between the light sensing area of the
image senser IS' and the image plane of the object in the
arrangement shown in FIG. 6(a).
FIG. 7 shows the electric block circuit diagram of an embodiment of
an ordinary camera in which the focus point detecting system using
the image senser IS' shown in FIG. 5 (a) and (b) in accordance with
the present invention is adopted.
FIG. 8 shows a diagram for showing the variation of the value
processed by the integrating circuit 109 corresponding to the
displacement of the photographic optics L during the operation of
the focus point detecting system shown in FIG. 7.
FIG. 9 shows a composition of important parts of the motion picture
camera in which such a focus point detecting system as is shown in
FIG. 7 is built in.
FIG. 10 shows an electrical block circuit diagram of an embodiment
of an ordinary camera in which a system for the exposure
measurement and the focus point detection by means of a common
image senser in accordance with the present invention is
adopted.
FIG. 11 shows a composition of important parts of the photographic
camera in which such a system as is shown in FIG. 10 is built
in.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Below several embodiments of the system for the exposure
measurement and/or the focus point detection of an image forming
optics by means of the image senser in accordance with the present
invention.
The embodiments of the exposure measuring system by means of the
image senser are shown in FIG. 1 to FIG. 4, the embodiments of the
focus point detecting system by means of the image senser are shown
in FIG. 5 to FIG. 9 and the embodiments of the system for the
exposure measurement and the focus point detection by means of a
common image senser are shown in FIG. 10 and FIG. 11.
First of all an embodiment of an ordinary camera in which the
system for the exposure measurement by means of the image senser in
accordance with the present invention is adopted will be explained
in accordance with FIG. 1 to FIG. 4.
FIG. 1 shows an embodiment of the arrangement of a plural number of
the fine light sensing elements in the image senser IS such as
photo diode array (MOS image senser), CCD (charge coupled devices)
and so on, whereby each of the fine light sensing elements is
provided at the position corresponding to each of the fine parts of
the image plane of the object to be photographed in such a manner
that the brightness of each of the fine parts of the object,
corresponding to each of the light sensing elements can be
detected.
This image senser IS is provided in place of the light measuring
element for the exposure measurement in the ordinary camera and
therefore for the position at which the image senser is provided
the neighborhood of the position equivalent to the image forming
plane of the photographic lens is suited in case of the internal
light measuring system (the so called TTL light measuring system
according to which the light beam coming from the photographic
field through the photographic lens is measured) and the view
finder optical path is suited in case of the conventional single
reflex camera, while the exposure measuring system in accordance
with the present invention is preferred to be provided at such a
position at which the light over almost all of the range of the
photographic field can be measured, whereby as is shown in FIG. 4
one reflecting face of the pentagonal prism composing a view finder
optics is made semipermeable in such a manner that the exposure
measuring system is cemented on the semipermeable face or provided
close to the semipermeable face.
In the image senser IS shown in FIG. 1, 1'.about.n' are the the
light sensing elements while Z.sub.1 is the spot zone for carrying
out a spot light measuring at the central part of the image plane
of the object to be photographed whereby the spot light measurement
is carried out by the light sensing elements n'-k'.about.n'
situated in this spot zone Z.sub.1, Z.sub.2 is the spot zone for
carrying out a spot light measuring at the left upper part of the
image plane of the object to be photographed whereby the spot light
measurement is carried out by means of the light sensing elements
1'.about.n-a ' situated in this spot zone Z.sub.2, Z.sub.3 is the
spot zone for carrying out a spot light measuring at the right
upper part of the image plane of the object to be photographed,
whereby the spot light measurement is carried out by means of the
light sensing elements n'-b'.about.n'-c' situated in this spot zone
Z.sub.3, Z.sub.4 is the spot zone for carrying out a spot light
measuring at the right lower part of the image plane of the object
to be photographed, whereby the spot light measurement is carried
out by means of the light sensing elements n'-d'.about.n'-e'
situated in this spot zone Z.sub.4. Z.sub.5 is the spot zone for
carrying out a spot light measuring at the left lower part of the
image plane of the object to be photographed, whereby the spot
light measurement is carried out by means of the light sensing
elements n'-.function..about.n'-g' situated in this spot zone
Z.sub.5.
FIG. 2 shows an electrical block wiring diagram of an embodiment of
the exposure measurement system in accordance with the present
invention by means of the image sensor IS shown in FIG. 1, whereby
in FIG. 2, 1'.about.n' are the light sensing elements shown in FIG.
1, which elements are connected in series with an analog switch 1
for transmitting the output signals of the light sensing elements
1'-n' to the operational amplifier 7 at the next step one after
another while the analog switch 1 is connected with the shift
register 2. The shift register 2 is connected with the gate control
circuit 3, which is controlled by the control signal of the ROM
(Read Only Memory) device 5. The gate control circuit 3 is so
constructed that by means of the signal of the ROM device the gate
circuit 17 is controlled. 6 is a diode for composing a
logarithmically compressing a circuit A together with the operation
amplifier 7, 10 is a clock pulse generator for producing standard
pulses by means of the signal from the ROM device 5 and is
connected with the D - A (Digital-Analog) converter 9 at whose
output terminal an output signal in form of step as is shown by
9.sub.0 in the drawing is produced. 8 is the comparison circuit
whose input terminal is connected with the operational amplifier 8
and the D - A converter 9 so as to compare the outputs of both
circuitries with each other. 11 is a gate connecting the comparison
circuit 8 with the clock pulse generator 10 and consisting of for
example conventional NAND circuit or the like. 12 is a counter
being controlled by means of the ROM device 5 and composing a A - D
(Analog-Digital) converter together with the clock pulse generator
10, the D - A converter 9, the comparison circuit 8 and the gate
circuit 11. 13 is the addition means whose input terminal is
connected with the output terminal of the counter 12 and with the
feed back path of the register in the next step being controlled by
means of the ROM device 5. 17 is a gate circuit which is so
constructed that in accordance with the selected gate of the ROM
selecting switch for example, in case the spot zone Z.sub.1 is
selected the content of the counter 12 is transmitted to the
addition means 18 by means of the signal of the gate control
circuit 5 when the light sensing elements n'-k' come in turn. 19 is
the register which is controlled by the ROM device 5 and fed back
to the addition means 18, whereby for example in case the spot zone
Z.sub.1 is selected the value of the light measurement of each
light sensing elements after the elements n'-k' is added one after
another. 20 is the division means which is controlled by the ROM
device 5 in such a manner that the content of the register 19 is
divided by the total number of the light sensing elements in the
respective spot zone, namely the total number (k'+1 in this case)
of the light sensing elements after the elements n'-k' in case the
spot zone Z.sub.1 is selected. 21 is a register which is connected
with the division means 20 so as to register the value obtained by
the division means 20. The gate circuit 17, the addition means 18,
the register 19, the division means 20 and the register 21 compose
the spot light measuring system C.
15 is a division means which is controlled by means of the ROM
device 5 in such a manner that the content of the register 14 is
divided by the total number (n') of the light sensing elements. 16
is a register which is connected with the division means 15, so as
to register the value obtained by the division means 15. The
addition means 13, the register 14, the division means 15 and the
register 16 composes the mean light measuring system D.
22 is the comparison means which is connected with both registers
16 and 21 in such a manner that the content of the register 16 is
compared with that of the register 21 in case by means of the ROM
selecting switch the control content Ra and either one of R.sub.1
-R.sub.5 are selected at the same time whereby the gate circuit is
brought in the switched on state in case there is an exposure
difference greater than .+-.2EV in the contents of both registers
while the gate circuits 23 and 24 are connected so as to bring the
gate circuit 23 in the switched on state in case there is an
exposure difference smaller than .+-.2EV in the content of both
registers. 25 is the operation means which is connected with the
output terminals of the gate circuit 23 and 24 in such a manner
that the information signal of the light measurement from the gate
circuit 23 or 24 is processed together with the logarithmically
compressed digital signal of the exposure factors such as shutter
time value 28, the diaphragm value 27, the ASA sensitivity and the
like so as to control the diaphragm control device 30 or the
shutter time control device 29 connected with the operation means
25, while at the same time, the operation means 25 is connected
with the ratch 31 being controlled by the ROM device 5 in such a
manner that the exposure information suited for the then
photographing is indicated by the indication device E consisting of
the decorder 32 and the indication member 33.
35 is the switching over switch for switching the diaphragm control
device 30 over to the shutter control device 29 while 34 is the
switching over switch for switching the shutter time value 28 over
to the diaphragm value 27.
ROM selecting switch 4 is the selecting switch for selecting the
control contents set in the ROM device 5. R.sub.1 is one of the
control contents set in the ROM device 5 whereby R.sub.1 is
intended to bring the gate circuit 17 in the switched on state
while the light sensing elements n'-k'.about.n' situated in the
spot zone Z.sub.1 are producing outputs, so as to carry out the
spot light measurement in the spot zone Z.sub.1. R.sub.2 is one of
the control contents set in the ROM device 5 whereby R.sub.2 is
intended to bring the gate circuit 17 in the switched on state
while the light sensing elements 1'.about.n'-a' situated in the
spot zone Z.sub.2 shown in FIG. 1 are producing outputs, so as to
carry out the spot light measurement in the spot zone Z.sub.2.
R.sub.3 is one of the control contents set in the ROM device 5,
whereby R.sub.3 is intended to bring the gate circuit 17 in the
switched on state while the light sensing elements
n'-b'.about.n'-c' situated in the spot zone Z.sub.3 shown in FIG. 1
are producing outputs, so as to carry out the spot light
measurement in the spot zone Z.sub.3. R.sub.4 is one of the control
contents set in the ROM device 5, whereby R.sub.4 is intended to
bring the gate circuit 17 in the switched on state while the light
sensing elements n'-d'.about.n'-e' situated in the spot zone
Z.sub.4 shown in FIG. 1 are producing outputs, so as to carry out
the spot light measurement in the spot zone R.sub.4. R.sub.5 is one
of the control contents set in the ROM device 5, where R.sub.5 is
intended to bring the gate circuit 17 in the switched on state
while the light sensing elements n'-.function..about.n'-g' situated
in the spot zone Z.sub.5 shown in FIG. 1 are producing outputs, so
as to carry out the spot light measurement in the spot zone
Z.sub.5. The control contents R.sub.1 -R.sub.5 are combined in such
a manner that the comparison circuit 22 and the gate circuit 23 are
out of operation while the gate circuit 24 is in operation when
either one of the control contents R.sub.1 -R.sub.5 is selected by
the ROM selecting switch 4.
R.sub.A is one of the control contents, whereby when only the
control content R.sub.A is selected by the ROM selecting switch 4,
the comparison circuit 22 and the gate circuit 24 are out of
operation while the gate circuit 23 is in operation. When the
control content R.sub.A and either one of the control contents
R.sub.1 .varies.R.sub.5 are selected at the same time by the ROM
control switch 4, the comparison circuit 22 is in operation while
the gate circuits 23 and 24 are controlled by the control signal of
the comparison circuit 22.
Below the concrete control method will be explained at the time the
outputs of the photo diodes are taken out one after another in case
as an example of the image senser IS a photo diode array (MOS image
senser) is adopted.
FIG. 3(a) shows an electrical circuit diagram of the electrical
connection among the photo diode array, the analog switch 1 and the
switch register 2 in case the photo diode array is adopted as image
senser, while FIG. 3(b) shows the timing chart for showing the
signal outputs taken out of the photo diodes one after another in
the electrical circuit shown in FIG. 3(a).
When in FIG. 3(a) the start pulse Vs' as is shown in FIG. 3(b) is
applied to the start pulse input terminal Vs in case the clock
pulses .phi..sub.1 ', .phi..sub.2 ' as is shown in FIG. 3(b) is
applied to the clock terminal .phi..sub.1, .phi..sub.2, a voltage
as is shown by VG.sub.1 ' in FIG. 3(b) is applied to the gate
VG.sub.1 of the first switch S.sub.1 of the analog 1 in such a
manner that the photo diode D.sub.1 produces an output
corresponding to the light in the photographic field. After a half
period of the clock pulse .phi..sub.1 ', .phi..sub.2 ' a voltage as
is shown by VG.sub.2 ' in FIG. 3(b) is applied to the gate VG.sub.2
of the second switch S.sub.2 of the analog switch 1 in such a
manner that the photo diode D.sub.2 produces an output
corresponding to the light of the photographic field. After another
half period of the clock pulse .phi..sub.1 ', .phi..sub.2 ' the
voltage VG.sub.1 ' applied to the gate VG.sub.1 of the first switch
S.sub.1 is reset so as to open the switch S.sub.1 and close the
switch at the next step in such a manner that the photo diode
connected with the switch at the next step produces an output.
During the repetition of the above mentioned operations the photo
diodes in the photo diodes array produce the output one after
another.
Below the operation of the exposure measurement system in
accordance with the present invention will be explained in
accordance with FIGS. 1 and 2.
A system as operated by closing a current supply switch not shown.
When the ROM selecting switch selects the control contents
(members) R.sub.1 and R.sub.A, the signal from the ROM device 5 and
the shift register 2 as well as the gate control circuit 3
cooperate to cause the first light sensing element 1' in the image
sensor IS to transmit its output to the logarithmically compressing
circuit A through the analog switch 1. The circuit A is composed of
the operational amplifier 7 and the diode 6. The circuit A
compresses its input signal logarithmically and applies to the
comparison circuit 8. At the same time the ROM device 5 causes the
clock pulse generator to produce clock pulses which are transmitted
to the D-A converter 9. The clock pulses are also transmitted by
the gate circuit 11 to the counter 12 so as to be counted in the
counter.
The D-A converter 9 produces a signal 9.sub.0 in the form of
staircase steps corresponding in number to the number of clock
pulses. The comparator 8 compares the logarithmically compressed
signal with the step signal 9.sub.o. When the values of both signal
are equal to each other, the comparison circuit 8 produces a
switching off or disabling signal. This disabling signal appears at
the gate circuit 11 and switches off or disables the gate circuit
11. This prevents the clock pulse from being transmitted to the
counter 12 while the digital signal corresponding to the output of
the light sensing element 1' is counted by the counter 12.
When the counter finishes the counting, the control signal of the
ROM device 5 causes the digital signal counted by the counter 12 to
be transmitted to the register 14 in the mean light measuring
system D through the addition means 13 so as to be registered
there.
When the register 14 has registered the digital signal, the control
signal by the ROM device 5 is transmitted to the gate control
circuit 3, whereby the output of the light sensing element 2' is
processed likely to the output of the light sensing element 1', so
as to be counted and then added to the digital signal corresponding
to the output registered in the register 14, of the light sensing
element 1' by the addition means 13 in such a manner that the sum
of the digital signals corresponding to the light sensing elements
1' and 2' is registered in the register 14.
Thus the output signals corresponding to the conditions of the
photographic field, if the light sensing elements down to the
element 3'.about.n' are added as digital signals one after another
in the register 14 so as to be registered there in such a manner
that in the register 14 the total sum of the digital signals
corresponding to the output signals of all the light sensing
elements 1'.about.n' in the image senser IS shown in FIG. 1 is
registered. In short the light sensing elements are arranged all
over the image plane as is shown in FIG. 1, so that in the register
14 a value n' times as large as the mean light measurement value is
registered.
When as mentioned above, the total sum of the digital signals
corresponding to the output of the light sensing elements
1'.about.n' is registered in the register 14 has been registered in
the register 14, the total sum of the digital signals is
transmitted by the ROM device 5 to the division means 15 so as to
be divided by the number (n') of all the light sensing elements and
registered in the register 16 as the mean light measurement
value.
When hereby as mentioned above the output of the light sensing
element n'-k' is processed during the light measuring process the
control signal from the ROM device 5 is transmitted to the gate
circuit 17 through the gate control circuit 3, so as to open the
gate circuit 17, whereby the digital signal counted by the counter
12, of the output of the light sensing element n'-k' is transmitted
to the mean light measuring system D and at the same time to the
addition means 18 of the spot light measuring system C in such a
manner that likely to the above mentioned operation of the mean
light measuring system D the total sum of the digital signals
corresponding to the outputs of the light sensing elements down to
the element n'-k'.about.n' is registered in the register 19. When
the total sum of the digital signals corresponding to the outputs
of the light sensing elements down to the element n'-k'.about.n'
has been registered in the register 19, the division means 20 is
put in the operation by means of the ROM device 5 in such a manner
that the total sum of the information signals n'-k'.about.n' is
divided by the number of the light sensing elements situated in the
spot zone Z.sub.1 so as to be registered in the register 21.
As is shown in FIG. 1, the light sensing elements n'-k'.about.n'
are arranged so as to measure the brightness of a part in the
middle of the image plane in the spot zone Z.sub.1 so that the
value of the spot light measurement in the part in the middle is
registered in the register 21.
The value registered in the register 21, of the spot light
measurement and the value registered in the register 16 of the mean
light measurement are transmitted by means of the signal from the
ROM device 5 to the comparison circuit 22 so as to be compared with
each other in such a manner that when the difference between the
exposure values more than .+-.2EV is detected between both values
the switching on signal of the comparison circuit 22 is transmitted
to the gate circuit 24, so as to close the gate circuit 24 and to
transmit the value registered in the register 21, of the spot light
measurement to the processing means 25 through the gate circuit 24,
while when the difference between the exposure values is smaller
than .+-.2EV the comparison circuit 22 transmits the switching on
signal to the gate circuit 23 so as to close the gate circuit 23 in
such a manner that the value registered in the register 16, of the
means light measurement is transmitted to the processing means 25
through the gate circuit 23. The value of the spot light
measurement or the value of the mean light measurement transmitted
to the processing means 25 is logarithmically compressed in
accordance with the connected state of the swich 34 and processed
together with the digital value of the shutter time 28 or the
diaphragm 27 and the ASA sensitivity 26 so as to be transmitted as
control signal for controlling the diaphragm control device 30 or
the shutter time control device 29 selectively to the device 29 or
30 in accordance with the connected state of the switch 35 in
functional engagement with the switch 34 and at the same time to
the indication device E consisting of the ratch 31, the decoder 32
and the indication member 33 to indicate the shutter time value or
the diaphraagm value. Hereby the swiches 34 and 35 shown in FIG. 2
are in the state in which the diaphragm value is controlled.
The above mentioned process corresponds with the case in which the
control contents R.sub.A and R.sub.1 are selected at the same time
by the ROM selecting switch 4, whereby when it is desired in
accordance with the condition of the photographic field that the
value of the spot light measurement at the left upper part in the
image plane of the object to be photographed is compared with the
value of the mean light measurement it is sufficient to select the
control contents R.sub.A and R.sub.2 at the same time by means of
the ROM selecting switch 4.
When in case of only the spot light measurement the control content
corresponding to the desired spot zone (for example spot zone
Z.sub.1) in the image plane of the object to be photographed is
selected by means of the ROM selecting switch 4, the value of the
spot light measurement in the spot zone Z.sub.1 is registered in
the register 21. As hereby only the control content R.sub.1 is
selected, the comparison circuit 22 and the gate circuit 23 are out
of operation and only the gate circuit 24 is in operation in such a
manner that the value registered in the register 21, of the spot
light measurement in the spot zone Z.sub.1 is transmitted to the
processing means 25 through the gate circuit 24, so as to be
controlled similarly to the case when R.sub.A and R.sub.2 are
selected.
When in case of only the mean light measurement only the control
content R.sub.A is selected by means of the ROM selecting switch 4
the gate circuit 17 is not switched on in such a manner that the
spot light measuring system C, the comparison circuit 22 and the
gate circuit 24 and out of operation while the gate circuit 23 is
in operation so that the value of the mean light measurement is
registered in the regiser 16 due to the operation similar to the
above mentioned process and transmitted to the processing means 25
through the gate circuit 23 so as to be controlled similarly to the
case when the control contents R.sub.A and R.sub.1 are
selected.
FIG. 4 shows an embodiment practically built in the ordinary
camera, of the above mentioned exposure measuring system in
accordance with the present invention.The camera shown in the
drawing is a conventional single reflex camera whereby in the
drawing only the important parts are shown for the sake of
simplicity.
In the drawing L.sub.1 is the conventional photographic optics
while 36 is the pentagonal prism composing the view finder optics
of the camera whereby the image senser IS is cemented on the
semipermeable face 36a of the pentagonal prism 36 or provided in
its neighborhood. 37 is the conventional photographic diaphragm
blade provided in the photographic optical path whereby the
diameter of the opening is controlled by means of the above
mentioned diaphragm control device 30, which is shown in dotted
line 30' in the drawing. 38 is the opening and closing member of
the conventional focal-plane-shutter whereby the opening and the
closing speed is controlled by means of the shutter time control
device, which is shown in the dotted line 29' in the drawing. 39 is
the film, while F is a circuit block including circuits 1 to 3 and
5 to 25 in FIG. 2.
When this camera is used, the switch 34 and the switch 35 is
functional engagement with the switch 34 is operated depending upon
whether the automatic control of the diaphragm (the so called
automatic diaphragm control method with priority on the shutter
time) or the automatic control of the diaphragm (the so called
automatic shutter time control method with priority on the
diaphragm) is desired (The state shown in the drawing corresponds
to the automatic shutter time control method with priority on the
diaphragm), whereby further the desired light measurement is
decided by means of the ROM selecting switch 4 as mentioned above.
Then the ASA sensitivity 26 is decided in accordance with the
sensitivity of the film 39 to be used while either the diaphragm
value 27 or the shutter time value 28 is decided in advance in
accordance with the method for controlling the exposure. (In the
state shown in the drawing the shutter time value 28 is decided in
advance because it is intended to control the diaphragm
automatically).
When after the above mentioned operation, the current source switch
not shown in the drawing is closed the exposure measurement system
is brought into operation likely to the case explained in
accordance with FIG. 1, whereby the exposure value then suited for
the photographic field, namely the shutter time value in case of
the automatic shutter time control or the diaphragm value in case
of the automatic diaphragm control (In consequence the diaphragm
value in the state shown in the drawing.) is indicated by the
indication device E in the view finder of the camera while either
the shutter time control device 29 or the diaphragm control device
30 operates in such a manner that the operating speed of the
shutter operating member 38 or the opening diameter of the
diaphragm blade 37 is automatically controlled so as to carry out
the automatic exposure control in accordance with the then
condition of the photographic field. Hereby in the state shown in
the drawing, the diaphragm control device 30 operates so as to
control the opening diameter of the diaphragm blade 37.
Thus, it is possible to take a photograph with the exposure value
suited for the then condition of the photographic field by
operating the conventional release button not shown in the drawing
in the above mentioned state.
In this way both the automatic exposure control with priority on
the shutter time and that with priority on the diaphragm are
possible in case of the exposure measurement system in accordance
with the present invention.
Especially in case of the exposure measurement in accordance with
the present invention as light sensing means an image senser
consisting of a number of fine light sensing elements such as MOS
image senser, CCD (Charge coupled devices) and so on is adopted
whereby by arranging each light senging element in the image senser
at the position corresponding to each fine part of the image plane
of the object to be photographed and by scanning the image plane of
the object to be photographed purely electrically by means of the
light sensing elements the brightness at each part corresponding to
each light sensing element, of the object to be photographed is
measured whereby a desired light measurement is carried out by
converting the output of each light sensing element into digital
value and selectively taking out the digital signal so that the
most suited light measurement is automatically selected, which
brings many profits to this kind of the light measurement, such as
capability for spot light measurement over a wide range of the
image plane of the object to be photographed, for automatically
selecting the light measurement most suited for the then
photographing conditions.
Hereby it goes without saying that it is possible to design the
present embodiment in such a manner that the shutter time control
device 29 and the diaphragm control device 30 are eliminated and
the shutter time or the diaphragm is manually controlled in
accordance with the exposure value indicated by the indication
device E. Further it is possible to provide only the shutter time
control device 29 or the diaphragm control device 30.
Below the focus point detecting system for detecting the focus
point of the image forming optics by means of the image senser in
accordance with the present invention will be explained in
accordance with an embodiment shown in FIGS. 5 to 9, whereby the
system is applied to the ordinary camera.
FIG. 5(a) shows the image senser suited for the focus point
detecting system in accordance with the present invention while
FIG. 5(b) shows a part thereof in enlargement, whereby the image
senser IS' is composed in such a manner that as is shown in the
drawing n fine light sensing elements with same dimension P.sub.1,
P.sub.2, P.sub.3 . . . P.sub.n-1, P.sub.n are arranged in form of
matrix on the base plate G.
The image senser IS' is placed at the position equivalent to the
film H relative to the photographic optical system L of the camera
as is generally shown in FIG. 6(a). HM is a small semipermeable
mirror provided slantwise on the optical axis of the photographic
optical system L between the photographic optical system L and the
film H, which small semipermeable mirror reflects the light beam at
the control part of the light beam coming from the object to be
photographed through the photographic optical system L so as to be
projected on the image senser IS'. In consequence, the image senser
IS' receives only the light beam at the central part H'a in the
image plane H' to be projected on the film H, of the object to be
photographed as is shown in FIG. 6(b).
FIG. 7 shows the block wiring diagram of the electrical circuit of
an embodiment of the focus point detecting system in accordance
with the present invention, utilizing the image senser IS' as is
shown in FIG. 5(a) and (b), whereby 101 is the X-coordinate shift
register presenting m X-coodinate axis X.sub.1, X.sub.2, . . .
X.sub.m-1, X.sub.m while 102 is the Y-coodinate shift register
presenting lY-coodinate axis Y.sub.1, Y.sub.2, . . . Y.sub.l-1,
Y.sub.l (hereby l=n/m) and a matrix is formed by these X and Y
coodinate axis. The light sensing elements P.sub.1, P.sub.2, . . .
P.sub.n in the image senser IS' are positioned one after another
relative the matrix so as to be connected with both X and Y
coodinate shift register 101 and 102. 103 is the logarithmic
amplifier for logarithmically compressing the output of each light
sensing element P.sub.1, P.sub.2, . . . Pn, 104 the A - D converter
for converting the analog amount into digital value, both 105 and
106 the registers and 107 the zero detecting circuit of the
register 106. 108 is the circuit for processing the absolute value
of the difference between the outputs of the registers 105 and 106,
whereby when for example, it is assumed that the content of the
register 106 be .alpha. while the content of th register 105 be
.beta., the value .vertline..alpha.-.beta..vertline. is produced.
109 is the integrating circuit, 110 the register, 111 the
comparison detecting device for comparing the output of the
register 110 with the output value of the integrating circuit 109
and 112 the driving source respectively the combined focus point
indication device of the photographic optical system. 113 is the
control circuit for central-controlling the circuit and the device
shown with 101 and 104 respectively 110.
Below the operation of the focus point detecting system composed as
above will be explained.
When the system is brought into operation by switching on the
current source not shown in the drawing, X.sub.1 and Y.sub.1 axis
of the shift registers 101 and 102 are switched on at first and in
consequence the output of the light sensing element P.sub.1 at the
coodinate (X.sub.1, Y.sub.1) is put in the logarithmical amplifier
103. After the analog output logarithmically compressed by the
logarithmic amplifier 103, of the light sensing element P.sub.1 is
converted into a digital value R.sub.1 by means of the A - D
converting device 104, the value R.sub.1 is registered in the
register 105. When at this time, other signal is registered in the
register 106, the the absolute value of the difference between the
signals registered in the registers 105 and 106 is immediately
processed, whereby however, no signal has been registered in the
register 106 and therefore the processing circuit 108 is not
brought into operation by the control circuit 113 with the signal
from the zero detecting circuit 107. Then by means of the signal
from the control circuit 113 the digital value r.sub.1 registered
in the register 105, of the output of the light sensing element
P.sub.1 is transferred to the register 106, while the coodinate
axis of the shift register 101 is shifted by one step in such a
manner that the X.sub.1 axis is switched over from the switched on
state to the switched off state while the X.sub.2 axis is switched
over from the switched off state to the switched on state, so that
now the output of the light sensing element P.sub.2 positioned at
the coordinate (X.sub.2, Y.sub.1) is registered as digital value in
the register 105 through the logarithmic amplifier 103 and the A -
D converting device similarly to the case of P.sub.1. When signals
are registered in the registers 105 and 106, the control circuit
113 immediately brings the processing circuit 108 into operation,
so as to process the absolute value of the difference between the
signals registered in the register 105 and 106, namely
.vertline.R.sub.1 -r.sub.2.vertline. and transfers the obtained
digital value to the integrating circuit 109 while the signal
registered in the register 105 is transferred to the register 106.
When then by means of the signal from the control circuit 113 the
coodinate axis of the shift register is further shifted by one
step, the output signal of the light sensing element P.sub.3 at the
coodinate (X.sub.3, Y.sub.1) is converted into an output r.sub.3
after the same process as before, the value
.vertline.r.sub.2-r3.vertline. is processed in the processing
circuit 108 and then transferred to the integrating circuit 109 so
as to be added to the former value .vertline.r.sub.1
-r.sub.2.vertline.. When after repetition of the same process the
shifting is finished up to the coodinate axis X.sub.m of the shift
register 101 (namely when the output signal of the light sensing
element P.sub.m at the coodinate (X.sub.m, Y.sub.1) has been
processed), the shift register 101 give an output signal CA.sub.1
to the shift register 102 in such a manner that the coodinate axis
of the shift register 102 is shifted similarly to the case of the
shift register 101. In this way, then the output signal of the
light sensing element P.sub.m+1 at the coodinate (X.sub.1, Y.sub.2)
is processed. When after repetition of the same process the output
signal is processed up to the last light sensing element P.sub.n at
the coodinate (X.sub.m, Y.sub.l), the shift register 102 gives an
output signal CA.sub.2 to the control circuit 113. The value
processed by the integrating circuit 109 at this time is ##EQU1##
namely the total sum of the absolute values of the differences
between the outputs of each pair of the light sensing elements
P.sub.1 .about.P.sub.n in the image senser IS' whereby the outputs
are logarithmically compressed, amplified and then converted into
digital values. Immediately upon receiving a signal CA.sub.2 from
the shift register 102 the control circuit 113 makes the comparison
device 111 compare the value processed by the integrating circuit
109 with the signal (at this time zero) registered in the register
110. After repetition of the same operation the variation of the
value .SIGMA. processed by the integrating circuit 109 is detected
by scanning different image planes by the light sensing elements
P.sub.1, P.sub.2, . . . P.sub.n. Namely, when while the
photographic optical system L shown in FIG. 6(a) is moved from the
position of focus at infinitive to that at the nearest distance,
the signals are processed as mentioned above, the value.SIGMA.
processed by the integrating circuit 109 at this time varies as is
shown in FIG. 8 in such a manner that the value is the largest at
the focussing position. This is due to the fact that when the
photographic optical system L reaches the focussing position the
image in the image senser IS' of the object to be photographed
becomes most sharp and therefore the then difference between the
outputs of the two adjacent light sensing elements in the image
senser IS' becomes largest. Namely, when the photographic optical
system is approaching the focussing position the value .SIGMA.
increases, when the system is at the focussing position the value
.SIGMA. is largest and when the system is leaving the focussing
point the value .SIGMA. decreases. Namely it is possible to find
out the focussing point by comparing the value .SIGMA. processed by
the integrating circuit 109 withe the next value .SIGMA. one after
another by means of the comparison circuit 111 so as to detect the
point of inflexion of the curve shown in FIG. 8.
When the first process has been completed from the output signal of
the light sensing element P.sub.1 to the output signal of the light
sensing element P.sub.n, the value processed by the integrating
circuit 109 is registered in the register 110. On the other hand at
this time, the X.sub.1 axis in the shift register 1 and the Y.sub.1
axis in the shift register 2 are respectively switched on, whereby
by means of the signal from the control circuit 113, the second
process begins from the output signal of the light sensing element
P.sub.1 to the output signal of the light sensing element P.sub.n.
Let the digital values of the outputs of the light sensing elements
P.sub.1, P.sub.2, . . . P.sub.n be r'.sub.1, r'.sub.2, . . .
r'.sub.n, the total sum of the values processed by the integrating
circuit 109 can be expressed by ##EQU2## likely to the former case.
As soon as the second process by means of the integrating circuit
109 has been completed the control circuit 113 makes the
commparison detecting device 111 compare the value processed by the
integrating circuit 109 ##EQU3## with the value registered in the
register 110 ##EQU4## when at this time, "the value registered in
the register 110" is smaller than "the value processed by the
integrating circuit 109", namely ##EQU5## the same process is
repeated until the value registered in the register 110 becomes
larger than the value processed by the integrating circuit 109,
when the comparison detecting device 111 gives a focussing signal
to the control circuit 113. By means of this signal, the control
circuit 113 stops the scanning of the image plane by means of the
light sensing elements P.sub.1, P.sub.2, . . . P.sub.n, at the same
time sending the focussing signal to the driving source of the
photographic optical system L respectively the focus point
indication device 112, so as to stop the photographic optical
system L at the focussing position respectively to indicate the
focus point.
Further, in the present embodiment the output of each light sensing
elements in the image senser IS' is logarithmically compressed,
amplified and then converted into a digital value whereby it goes
without saying that the output to each light sensing element can
directly converted into a digital value without being
logarithmically compressed and amplified. However, in case the
output of each light sensing element is logarithmically compressed
and amplified, the noise in the scanning signal can be kept as
small as possible even if the brightness of the object to be
photographed to some extent during the scanning of the image
pattern of the object to be photographed by means of the light
sensing elements and therefore the erroneous operation of the focus
point detecting device can be avoided.
As the image senser capable of being utilized in the focus point
detecting system in accordance with the present invention, apart
from the image senser presenting an arrangement pattern of the
light sensing elements as shown in FIG. 5 (a) and (b), the image
senser IS' presenting an arrangement pattern of the light sensing
elements as shown in FIG. 1 can also serve whereby various
variation of the arrangement pattern of the light sensing elements
are possible.
An embodiment of the focus point detecting system in accordance
with the present invention, mentioned above and practically built
in the ordinary camera is shown generally in FIG. 9. The camera in
the drawing is a conventional motion picture camera, whereby only
the important parts are shown.
In the drawing, among the photo-lens groups L.sub.2, L.sub.3 and
L.sub.4, the first and the second lens group L.sub.2 and L.sub.3
are utilized in common as an objective lens for range detecting.
Hereby the lens group L.sub.2 is kept by a lens barrel 114
presenting a rack 114a and moved along its optical axis by means of
the rotations of the motor 112a through a gear 115 fixed to the
rotational shaft 112a' of the motor. Between the lens group L.sub.3
and the lens group L.sub.4 a light beam splitter 116 presenting two
semi-permeable mirrors 116a and 116b is disposed. A lens group
L.sub.5, a reflecting prism 117 and a lens group L.sub.6 compose a
view finder optical system. The semi-permeable mirror 116a is
disposed slantly to the optical axis so that the light beam coming
from the lens group L.sub.3 to the film H may be split toward the
view finder optical system. In the optical path toward the view
finder optical system from the mirror 116a is disposed another
semi-permeable mirror 116a so that the light beam may be further
split into an image reforming lens 118.
The image senser IS' is disposed behind this image reforming lens
118 and at a position equivalent to that of the film H relative to
the lens groups L.sub.2 and L.sub.3.
112b is the indication device disposed in the view finder optical
path in such a manner that the indication can be recognized in the
view finder of the camera, J the circuit block including elements
shown with 101 to 111 and 113 in FIG. 7, whereby the indication
device 112b is connected with the output terminal of the circuit
block J together with the motor 112a. Namely, the motor 112a and
the indication device 112b correspond to the block 112 in FIG.
7.
121 is a spring disposed between the lens barrel 114 and the camera
body by means of which spring the lens barrel 114 is forced to the
right in the drawing namely in such a manner that the lens group
L.sub.2 is normally kept at the focus position at infinitive
distance.
119 and 120 are the shutter and the diaphragm in the conventional
motion picture camera, 122 a two step release button so constructed
that the focus detecting system is actuated at the first step while
the shutter is actuated at the second step.
When the motion picture camera constructed as mentioned above is
directed toward the desired object to be photographed and the
release button is pushed down to the first step, the circuit block
J is brought into operation and the focus detecting operation of
the photographic optical system begins. Namely, the image pattern
of the object to be photographed is scanned by means of the image
senser IS', whereby by means of the output given from the circuit
block due to the above scanning signal the motor 112a runs along
the direction of the arrow in the drawing in such a manner that the
lens group L.sub.2 is advanced from the focus position at
infinitive distance along the direction of the arrow in the drawing
against the strength of the spring 121. When the lens group L.sub.2
reaches the focussing position of the object to be photographed
during the advance movement the image of the object to be
photographed becomes sharpest on the image senser IS', when by
means of the scanning signal of the image senser IS' the circuit
block J immediately stops the motor 112a, so as to keep the lens
group L.sub.2 at this focussing position, at the same time,
actuating the indication device 112b so as to indicate that the
lens group L.sub.2 is at the focussing position. In this state, the
image of the object to be photographed is sharpest on the film
H.
Consequently, when in this state the release button 122 is pushed
down to the second step the shutter 119 is operated so as to expose
the film H on which the sharpest image of the object to be
photographed is obtained.
Further, when the release button 122 is freed, the current supply
to the circuit block J is interrupted so that the lens group
L.sub.2 is automatically returned to the focus position at
infinitive distance by means of the spring 121.
As explained above, in case of the focus point detecting system in
accordance with the present invention the image pattern of the
object to be photographed is scanned purely electrically, whereby
the mechanical scanning device in the conventional system is not
necessary, so that the focus point detecting device can easily be
made compact in accordance with the present invention, which is
quite profitable for small optical instrument such as camera.
Further in case of the focus point detecting system in accordance
with the present invention the output of each light sensing element
is processed after being converted into digital value, so that the
electrical processing is remarkably easy as compared with the
conventional system processing analog amount while at the same
time, the accuracy of the focus point detection can extremely
increased as compared with the conventional system. Further in case
of the focus point detecting system in accordance with the present
invention, the image pattern of the object to be photographed can
be scanned at a very high speed so that an exact focussing signal
can be obtained.
Hereby, it goes without saying that the driving source shown
symbolically with the motor 112a (in FIG. 9), for the automatic
focus adjustment of the optical system can be eliminated in such a
manner that the focus adjustment of the optical system is manually
carried out by the focus point indication device.
Further, it goes without saying that the focus point detecting
device or the automatic focus point adjusting device in accordance
with the present invention can be embodied as the device to be
built in the optical instruments such as camera or the independent
device to be used with the optical instrument. Hereby in case of
the independent device a distance measuring device can easily be
obtained when the focus point indication point, indication device
in the embodiment is exchanged for the distance indicator.
Below an embodiment of the system for exposure measurement as well
as for focus point detection by means of a common image senser in
accordance with the present invention will be explained in
accordance with the FIGS. 10 and 11, whereby the system is applied
to the general camera.
FIG. 10 is a block wiring diagram for the electric circuit of an
embodiment of the system capable of exposure measurement as well as
the focus point detection of the optical system by means of a
common image senser.
In case of the embodiment of the system shown in FIG. 10, not only
the image sense IS shown in FIG. 1 as well as the image senser IS'
shown in FIG. 5(a) and (b), but also the image senser presenting
other arrangement pattern of the light sensing elements can be
utilized. However, hereby the case in which the image senser IS
shown in FIG. 1 will be explained.
In the drawing, 201 is the shift register, 202 the analog switch
being connected with each light sensing element, 203 the
logarithmic amplifier for logarithmically compressing and
amplifying the output of each light sensing element in the image
senser IS, 204 the A-D converter for converting each output of the
logarithmic amplifier into the digital value, 205 and 207 the
registers and 206, 209, 212 and 213 the gate circuits. 208 is the
processing circuit for processing the absolute value of the
difference between two signal values registered in the registers
205 and 207, 210 the addition means for adding the value processed
by the processing circuit 208 to the signal value registered in the
register 211, 214 and 215 the registers, 216 the comparison
detecting device for comparing the signal value registered in the
register 211 with that registered in the register 215, 217 the
driving source of the photographic optical system and 217' the
focus point indication device. 218 is the deviding circuit for
deviding the signal value registered in the register 211, 219 the
processing means for logarithmically compressing, amplifying and
processing the output of the deviding circuit 218 together with the
shutter time value Tv respectively the diaphragm value Av converted
in a digital value and the film sensitivity value Sv in order to
obtain the exposure value, 220 the diaphragm control device, 220'
the shutter time control device, 220" the exposure value indication
device, 221 the control circuit for controlling the whole system
and 222 the switching over switch for switching the one exposure
control system over into the other system.
The image senser IS is placed at the image forming position or at a
position equivalent to the image forming position of the
photographic optical system not shown in the drawing or of the
image forming position of the image forming optical system for the
image senser IS.
In the above mentioned composition the focus point detecting system
consists of IS and the element 201 to 208, 210, 211 and 213 to 216
while the exposure measuring system consists of IS and the elements
201 to 205, 209 to 212, 218 and 219.
Below the operation of the above mentioned system will be
explained.
In order to detect the focus point of the optical system the
current switch not shown in the drawing is closed to operate the
system, whereby by means of the control signal produced in the
control circuit 221 the gate circuits 206 and 213 are brought into
the switched on state (hereby the gate circuit 209 and 212 are kept
in the switched off state), while the shift operator 201 starts to
operate. In the analog switch 202 the switching element
corresponding to each of the light sensing elements 1',2', . . . n'
in the image senser IS is provided in such a manner that there
switching elements operate one after another when the shift
register 201 is shifted by one step. When at first by means of the
shift register 201 the first switching element corresponding the
light sensing element 1', in the analog switch 202, the output of
the light sensing element 1' is transferred to the logarithmic
amplifier 203 through the analog switch 202 so as to be
logarithmically compressed and amplified. The analog amount of the
output of the light sensing element 1' logarithmically compressed
and amplified by the logarithmic amplifier 203 is converted into a
digital value P.sub.1 by means of the A - D converting device 204
and then registered in the register 205. If at this time, a signal
value were registered in the registere 207, the control circuit 221
immediately should send a control signal to the processing circuit
208, so that the processing circuit 208 might process the absolute
value of the difference between the signal values registered in
both registers 205 and 207.
However, at this time no signal value is registered in the register
207, so that the control circuit 221 does not bring the processing
circuit 208 into operation. Then by means of the control signal
produced by the control circuit 221 the signal value registered in
the register 205, namely the digital value of the output of the
light sensing element 1' logarithmically compressed and amplified
is registered in the register 207 through the gate circuit 206,
while at the same time, the shift register 201 is shifted by one
step. Thus the first switching element corresponding to the light
sensing element 1', of the analog switch 202 is brought into
switched off state, while the second switching element
corresponding to the light sensing element 2' is brought into
switch on state, so that likely to the case of the output of the
light sensing element 1', the output of the light sensing element
2' is processed and registered in the register 205 as signal value
P.sub.2. When a signal value is registered in the register 205, the
control circuit 221 sends a control signal to the processing
circuit 208, so as to process the absoute value of the difference
between the signal values registered in the registers 205 and 207.
Therefore, the then value processed by the processing circuit can
be expressed in .vertline.P.sub.1-P.sub.2 .vertline.. The value
processed by the processing circuit 208 is added to the signal
value registered in the register 211 (the signal value registered
in the register 211 is zero) by means of the addition means 210 and
registered in the register 211 (therefore the value registered in
the register 211 at this time is .vertline.P.sub.1 -P.sub.2
.vertline.). Then by means of the signal value registered in the
register 205 comes to be registered in the register 207 through the
gate circuit 206 (namely in the register 207 the signal value
P.sub.2 of the output of the light sensing element 2' is registered
in place of the signal value P.sub.1 of the output of the light
sensing element 1'), whereby likely to the above mentioned case, by
means of the control signal produced by the control circuit 221 the
shift register 201 is shifted further by one step in such a manner
that the output of the light sensing element 3' is processed likely
to the above mentioned two cases so as to be registered in the
register 205 as signal value P.sub.3. When a signal value is
registered in the register 205, the control circuit 221 actuates
the processing circuit 208, so as to carry out the same process as
mentioned above. Thus the then value processed by the processing
circuit 208 is .vertline.P.sub.2 -P.sub.3 .vertline., which value
is added to the then value .vertline.P.sub.1 -P.sub.2 registered in
the register 211 and then registered in the register 211. In
consequence the then value registered in the register 211 is
.vertline.P.sub.1 -P.sub.2 .vertline.+.vertline.P.sub.2 -P.sub.3
.vertline.. The same process is repeated until the output of the
light sensing element n' has been processed. The value registered
in the register 211 when all the output of the light sensing
elements down to n' is ##EQU6## namely the total sum of the
absolute values of the differences of the outputs between two
adjacent light sensing elements in the image senser IS, whereby the
output of each light sensing element is logarithmically compressed
and converted into a digital value. The then value registered in
the register 211 ##EQU7## is immediately registered in the register
214 through the gate circuit 213 by means of the control signal
produced by the control circuit 221. The value registered in the
register 214 is compared with the signal value registered in the
register 215 by means of the comparison detecting device 216.
Namely, the then value registered in the register 215 is zero and
further ##EQU8## is larger than zero so that the value registered
in the register 214 is larger than the value registered in the
register 215.
In this way, the variation of the value .SIGMA. processed by the
addition means 210 and registered in the register 211 is detected
by scanning the image plane by means of the light sensing elements
1', 2', . . . n' and repeating the above mentioned process. Namely,
when the signals are processed as mentioned above, while the image
forming optical system not shown in the drawing, for the image
senser IS is moved for example, from the focus point at infinite
distance to the focus point at the nearest distance, the value
processed by the addition means 210 and registered in the register
214 .SIGMA. varies as is shown in FIG. 8 likely to the case of the
focus point detecting system shown in FIG. 7, whereby the value
becomes largest at the focussing position. Namely, when the image
forming optical system approaches the focussing position, the value
.SIGMA. increases, when the image forming optical system is at the
focussing position, the value .SIGMA. is largest and when the image
forming system leaves the focussing position the value .SIGMA.
decreases. Consequently, it is possible to obtain the focussing
point when the maximum value of the .SIGMA. namely, the inflection
point of the curve shown in FIG. 8 is detected by comparing the
value .SIGMA. with the next value .SIGMA. processed by the addition
means 210 and registered in the register 214 one after another.
Because the scanning signal namely ##EQU9## obtained at the first
scanning of the image of the object to be photographed by means of
the light sensing elements 1', 2', . . . n' is larger than the then
value registered in the register 215, the control circuit 221
produces a control signal so that the value registered in the
register 214 is transferred to the register 215 while the shift
register 201 is reset in such a manner that the second scanning of
the image of the object to be photographed started by moving the
image forming optical system not shown in the drawing. Thus, let
the digital values of the outputs of the light sensing element
P'.sub.1, P'.sub.2, . . . P'.sub.n, so the total sum of the value
processed by the addition means 210 and registered in the register
214 can be expressed in ##EQU10## likely to the former case. As
soon as a new signal value is registered in the register 214, the
control circuit 221 brings the comparison detecting means 216 into
operation so as to compare the signal value registered in the
register 214 with that registered in the register 215, whereby when
at this time "the value registered in the register 214" is larger
than "the value registered in the register 215" (namely in this
case ##EQU11## the scanning of the image of the object to be
photographed is continued until the value registered in the
register 214 is smaller than the value registered in the register
215 ##EQU12## when the comparison detecting means 216 sends a
signal to the control circuit 221. Hereby the fact that the value
registered in the register 214 becomes smaller than the value
registered in the register 215 means that the value .SIGMA.
processed by the addition means 210 and registered in the register
214 reaches the maximum, namely the highest point in the drawing
shown in FIG. 8, namely the photographic optical system not shown
in the drawing reaches the focussing point. Consequently, the
signal produced by the comparison detecting means 216 is the
focussing signal. By means of this focussing signal the control
circuit 221 immediately the scanning of the image of the object to
be photographed by means of the light sensing elements 1', 2', . .
. n', at the same time sending a control signal to the driving
source 217 of the photographic optical system and the focus point
indication means 217' so as to stop the driving means of the
photographic optical system and indicate that the focussing
position has been obtained. Hereby it is also possible to eliminate
the driving source 217 whereby the focus position of the
photographic optical system can be obtained by adjusting the
photographic optical system by means of the focus point indication
device 217'.
Below the operation at the exposure measurement will be explained.
When the focus adjustment of the photographic optical system has
been completed the control circuit 221 produces a control signal in
such a manner that the gate circuits 209 and 212 are switched from
the switched off state over into the switched on state while the
gate circuits 206 and 213 are switched from the switched on state
over into the switched off state. When in this state, the control
signal is transferred from the control circuit 221 to the shift
register 201, the shift register 201 brings the first switching
element in the analog switch 202 corresponding to the light sensing
element 1' into the switched on state so as to transfer the output
of the light sensing element 1' to the analog amplifier 203 which
logarithmically compresses and amplifies the output of the light
sensing element 1'. The output logarithmically compressed and
amplified, of the light sensing element 1' is converted into a
digital value by means of the A-D converting means 204 and
registered in the register 205. After then by means of the control
signal produced by the control circuit 221 the signal value
registered in the register 205, of the output of the light sensing
element 1' is transferred to the register 211 through the gate
circuit 209 and the addition means 210.
When the signal value registered in the register 205 is transferred
to the register 211, the control circuit 221 sends a control signal
to the shift register 201, bringing the second switching element
corresponding to the light sensing element 2', in the analog switch
202 into switched on state so as to transfer the output of the
light sensing element 2' to the logarithmic amplifier 203, whereby
the output of the light sensing element 2' is processed likely to
the case of the light sensing element 1', registered in the
register 205 and transferred to the addition means 210 through the
gate circuit 209. After being added to the signal value registered
in the register 211, of the output of the light sensing element 1',
the signal value transmitted to the addition means 210, of the
output of the light sensing element 2' is again registered in the
shift register 211. Then the same process is repeated down to the
light sensing element n, whereby in the register 211 the total sum
of the signal values of the outputs of the light sensing elements
1' to n', is registered. When the total sum of the signal values of
the outputs of the light sensing elements 1' to n' has been
registered in the register 211, the control circuit 221 sends a
control signal to the shift register 201 so as to bring the shift
register 201 out of operation and transfer the total sum of the
signal values registered in the register 211, of the output of the
light sensing elements 1' to n' to the division circuit 218. As the
division circuit 218 has been programmed in advance in such a
manner that the value registered in the register 211 might be
devided by the total number (n') of the light sensing elements, the
then signal value registered in the register 211 is devided by the
total number (n') of the light sensing elements and led to the
processing means 219 as the value of the measured light of the
object to be photographed.
On the other hand, at this time, depending upon the exposure
control system selected by the switch 222 namely according to
whether the diaphragm is to be contolled automatically by means of
the diaphragm control device 220 or the shutter time is to be
controlled automatically by means of the shutter time control
device 220' the shutter time value T.nu. logarithmically
compressed, amplified and converted into digital value or the
diaphragm value A.nu. also logarithmically compressed, amplified
and converted into digital value has been given to the processing
means 219 together with the film sensitivity S.nu. also
logarithmically compressed, amplified and converted into digital
value in such a manner that the processing means 219 processes the
above mentioned value of the measured light of the object to be
photographed together with the shutter speed value T.nu. and the
film sensitivity S.nu. or with the diaphragm value A.nu. and the
film sensitivity S.nu. so as to produce the exposure value.
Depending upon the connected state of the switch 222 the exposure
value is given to the diaphragm control device 220 or to the
shutter time control device 220' in such a manner that the
diaphragm value or the shutter time value is automatically
controlled while the then exposure value, namely the diaphragm
value or the shutter time value is indicated by means of the
indication device 220". Thus all the exposure measurement operation
has been completed.
FIG. 11 shows generally an embodiment of the syste for measuring
the exposure and detecting the focus point by means of a common
image senser in accordance with the present invention, whereby the
system is built in a practical camera. In the drawing L.sub.7 is
the photographic optical system been held by means of the lens
barrel 223 and movable along the optical axis, whereby the optical
system L.sub.7 is forced to the right in the drawing by means of a
spring 224 provided between the lens barrel 223 and the camera body
so as to normally assume the focus position at the infinitive
distance by the effect of the spring.
On one part of the lens barrel 223 a rack 223a is provided in such
a manner that the rack 223a is engaged with the gear 227 provided
on the output shaft 217a of the driving source 217 of the
photographic optical system L.sub.7, whereby in the drawing the
driving source 217 is shown as a motor.
L.sub.8 is the additional image forming optical system for
measuring the light and the distance, being held by means of the
lens barrel 225 connected by means of a joint member 226 with the
lens barrel 223 holding the photographic optical system L.sub.7 and
movable along the optical axis in functional engagement with the
photographic optical system. The above mentioned image senser IS is
provided in the optical path of the image forming optical system
L.sub.8.
228 is the conventional diaphragm blade provided in the above
mentioned lens barrel 223 wherby the diameter of the opening is
controlled by means of the above mentioned diaphragm control device
220. The state is shown generally by the dotted line 228' in the
drawing.
229 is the operation member for the conventional focal plane
shutter, whereby the operation speed is controlled by means of the
above mentioned shutter time control device 220'. The state is
generally shown by the dotted line 229' in the drawing.
230 is the film, 231 the movable mirror of the conventional single
reflex camera, M the circuit block including circuitries 201-216,
218, 219 and 221 in FIG. 10 and 232 the two step release button
constructed in such a manner that the circuit block M is brought
into operation at the first step, while the movable mirror and the
shutter are brought into operation at the second step.
The above mentioned focussing position indication device 217' and
the above mentioned exposure value indication device 220" is
provided, as shown in the drawing, in the optical path of the view
finder in such a manner that the indication can be seen in the view
finder.
Below the operation of the above mentioned camera will be
explained. When the camera is directed toward the desired object to
be photographed and the release button 232 is pushed down to the
first step, the circuit block M is brought into operation so as to
start the focus point detecting operation of the photographic
optical system as well as the exposure measurement operation as
mentioned above.
Namely at first by means of the image sensor IS the image formed by
the image forming optical system L.sub.8, of the object to be
photographed is scanned and then the motor 217 starts to rotate
along the direction of the arrow in the drawing by means of the
output of the circuit block M due to the then scanning signal in
such a manner that the photographic optical system L.sub.7 is
advance along the direction of the arrow in the drawing from the
focus point at infinitive distance against the strength of the
spring 224. At this time, the image forming optical system L.sub.8
also advances along the direction of the arrow in the drawing in
functional engagement of the photographic optical system L.sub.7,
whereby when the both optical systems L.sub.7 and L.sub.8 reach the
focussing position of the object to be photographed during the
advance process of these optical systems L.sub.7 and L.sub.8, the
image formed on the image senser IS by means of the optical system
L.sub.8, of the object to be photographed is sharpest in such a
manner that the circuit block M immediately stops the motor 217 by
means of the then scanning signal of the image senser IS so as to
hold the both optical systems L.sub.7 and L.sub.8 at this focussing
position and at the same time brings the focus point indication
device 217' into operation so as to indicate that the photographic
optical system L.sub.7 reaches the focussing position. In this
state, the image of the object to be photographed in sharpest on
the film 230.
As soon as the focus point adjusting operation of the photographic
optical system L.sub.7 has been finished, the system assumes the
exposure measurement operation. The then state of the exposure
control is determined in accordance with the selected state of the
switch 222. Namely when the switch 222 is connected with the
diaphragm control device 220 the diaphragm is automatically
controlled with priority on shutter time while the switch 222 is
connected with the shutter time control device 220' the shutter
time is automatically controlled with priority on diaphragm. (In
the state shown in the drawing the diaphragm is automatically
controlled.)
In consequence at the time of the exposure measurement, it is
necessary for the photographer to determine the state of the
exposure control by means of the switch, giving in advance to the
circuit block M, the film sensitivity value S.nu. and the shutter
time value T.nu., when the automatic diaphragm control is desired
and the film sensitivity value S.nu. and the diaphragm value A.nu.
when the automatic diaphragm control is desired. (In consequence,
in the state shown in the drawing the shutter time value T.nu. has
to be determined in advance.)
By means of the above mentioned operation, the system processes the
exposure value suited for the then conditions of the photographic
field from the value of the measured light of the photographic
field of the image sensor IS, the film sensitivity S.nu. and the
shutter time value T.nu. or the diaphragm value A.nu., namely the
shutter time value in case of the automatic shutter time control
and the diaphragm value in case of the automatic diaphragm control
so as to indicate it by the indication device 220", while in case
of the automatic shutter time control the operating speed of the
operating member 229 is automatically controlled by means of the
control device 220' and in case of the automatic diaphragm control
the diameter of the opening of the diaphragm blade 228 is
automatically controlled by means of the control device 220. Thus
the automatic control of the exposure suited for the then condition
of the photographic field has been completed.
When in this state, the release button 232 is pushed down to the
second step the movable mirror 231 is retired out of the
photographic optical path while the shutter is operated so as to
exposure the film 230 at the proper focussing and the proper
exposure.
When the release button 232 is returned to the initial position the
current supply to the circuit block M is interrupted so that the
photographic optical system L.sub.7 is automatically returned to
the focussing position at infinitive distance by means of the
strength of the spring 224.
As explained above, in case of the system for the focus detection
and the exposure measurement by means of a common image senser in
accordance with the present invention, the light sensing device to
be used in common for the focus detection and the exposure
measurement consists of a number of fine light sensing elements
while the output of each light sensing element is processed after
having been converted into digital value so that the electrical
processing is remarkably easy as compared with the conventional
system in which the signal is processed as analog amount, whereby
the sigal processing circuit is remarkably simplified while the
signal process is controlled with high stability so that it is
possible to keep the measurement error at the signal process as
small as possible. Especially in case of the system in accordance
with the present invention all the signal processing is controlled
in a digital way so that the control at the signal processing
becomes much simplified whereby it is possible to apply a number of
the light sensing elements in the light sensing device and
therefore a further exact measurement.
Hereby in case of the present invention, it goes without saying
that the diaphragm diameter or the shutter time can manually be
controlled in accordance with the exposure value indicated by means
of the indication device 220", eliminating the diaphragm control
device 220 and the shutter time control device 220' or that only
the control device 220 or 220' is provided.
Further, it is also possible to eliminate the driving source 217
for the automatic focus point adjustment of the optical system so
as to manually adjust the focussing position of the photographic
optical system by means of the indication device 217'.
* * * * *