JP4186243B2 - Camera with focus detection device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a pupil time-division type image shift detection method that detects an image shift by alternately switching apertures provided in the vicinity of an exit pupil position of an optical system.ScorchingThe present invention relates to a camera with a point detection device.
[0002]
[Prior art]
As a conventional focus detection device, there is known a pupil time division type image shift detection type focus detection device that detects an image shift by alternately using a pair of apertures provided in the vicinity of an exit pupil position of an optical system. ing. This focus detection apparatus has the following configuration. That is, a pair of apertures provided in the vicinity of the exit pupil of the photographic optical system are alternately switched to form subject images (hereinafter referred to as a pair of subject images) alternately on the imaging surface of the photographic optical system. The pair of subject images are alternately photoelectrically converted in synchronism with the switching of the aperture by an image sensor disposed on the imaging surface of the photographing optical system. Therefore, the image sensor outputs a pair of image data corresponding to the pair of subject images. The focus state of the photographic optical system is obtained by detecting a shift between the pair of image data.
[0003]
The following means are known as means for alternately opening and closing the pair of openings. That is, TN (TWISTED NEMATIC) liquid crystal or GH (GUEST HOST) liquid crystal is used as means for alternately opening and closing the pair of openings. And a pair of opening formed with TN liquid crystal or GH liquid crystal is electrically controlled, and opens and closes alternately by time division. Charge accumulation is performed by a CCD image sensor provided on the imaging surface of the photographing optical system in synchronization with the opening and closing of the pair of openings formed by the liquid crystal.
[0004]
FIGS. 68A and 68B are diagrams showing a specific example of controlling the opening and closing of the pair of openings using TN liquid crystal.
As shown, the TN liquid crystal has the following configuration. That is, the substrate sandwiching the liquid crystal molecules 300 includes a glass substrate 310, a polarizing plate 330 or 340 provided on the outer surface of the glass substrate 310, and a transparent electrode 320 provided on the inner surface of the glass substrate 310. Here, the polarizing plates 330 and 340 are provided in an arrangement in which the polarization directions are orthogonal to each other. The liquid crystal shutter is provided with a power supply 350 and a switch 360. The power source 350 applies a voltage between the transparent electrodes 320.
[0005]
As shown in FIG. 68A, when the switch 360 is turned off and no voltage is applied between the transparent electrodes 320, the following operation is performed. That is, the liquid crystal molecules 300 are aligned in the parallel direction with respect to the transparent electrode 320, and the polarization direction of incident light is rotated by 90 degrees in the layer of the liquid crystal molecules 300. Therefore, the incident light passes through the exit-side polarizing plate 34 as it is.
[0006]
As shown in FIG. 68B, when the switch 360 is turned on and a voltage is applied between the transparent electrodes 320, the following operation is performed. That is, the liquid crystal molecules 300 are aligned in the direction perpendicular to the transparent electrode 320, and the polarization direction of incident light is not rotated in the layer of the liquid crystal molecules 300. Accordingly, the incident light is blocked by the polarizing plate 340 on the output side and cannot pass through.
[0007]
In the case of a TN liquid crystal, the incident light can be transmitted when the switch 360 is turned on, and the incident light can be blocked when the switch 360 is turned off, depending on the characteristics of the polarizing plates 330 and 340.
[0008]
FIGS. 69A and 69B are diagrams showing a specific example of controlling the opening and closing of the pair of openings using a GH liquid crystal. As shown, the GH liquid crystal has the following configuration. That is, the liquid crystal molecules 300 sandwiched between the glass substrates 310 are sandwiched so that the alignment direction is twisted, and the dichroic dye molecules 37 are aligned according to the liquid crystal molecules 300. A transparent electrode 320 is formed on the inner surface of the glass substrate 310, and a voltage is applied to the transparent electrode 320 by a power source 350 and a switch 360.
[0009]
The dichroic dye molecule 370 has a property of not absorbing light incident perpendicular to the molecular axis. Therefore, as shown in FIG. 69 (a), when no voltage is applied between the transparent electrodes 320, the incident light beam is blocked and shielded by the dichroic dye molecules 370 oriented in various directions.
In addition, as shown in FIG. 69 (b), when a voltage is applied between the transparent electrodes 320, the liquid crystal molecules 300 are aligned in a direction perpendicular to the transparent electrodes, and the dichroic dye molecules 370 are also transparent. Since it is oriented in the direction perpendicular to the electrodes, the incident light passes through it without being absorbed by the layer of dichroic dye molecules 370.
[0010]
[Problems to be solved by the invention]
The means for forming a pair of openings using the above-described TN liquid crystal or GH liquid crystal has the following problems.
First, even in the light transmission state, due to the presence of polarizing plates and dye molecules, the light transmittance is low, and high-speed operation for focus detection is difficult.
[0011]
Second, when assembling a device using TN liquid crystal or GH liquid crystal, a liquid crystal alignment step is required, which requires labor and great cost for manufacturing.
Thirdly, in devices using GH liquid crystal, a voltage must be applied in order to obtain a light transmission state. Therefore, when applied to a single-lens reflex camera or the like, the finder is shielded from light when the camera is turned off. It becomes impossible.
[0012]
Fourth, as described above, the device using the TN liquid crystal is in a light transmission state in the voltage non-application state due to the characteristics of the polarizing plate. However, in the case of a device using a TN liquid crystal that is in a light transmission state when no voltage is applied, in addition to the first and second problems, there are the following problems. For example, when applied to a camera, when the camera is turned off, the viewfinder becomes dark due to the presence of the polarizing plate, making observation difficult.
[0013]
  The present invention has been made in view of the problems of the prior art described above,Providing a camera with a focus detection device that uses a pupil time-division type image shift detection method that uses a device that has high transmittance during light transmission and does not require an alignment process, even when applied to a single-lens reflex camera, etc. It is an object of the present invention to provide a camera with a focus detection device of a pupil time division type image shift detection method capable of observing a bright screen with a finder.
[0015]
[Means for Solving the Problems]
  The first camera with a focus detection device is disposed on an imaging surface of a photographing optical system that forms a light flux from a subject, photoelectric conversion means for converting the subject image into an image signal, and the photographing optical system An observation optical system capable of observing an image of a subject, and a plurality of openings arranged in an optical path between the photographing optical system and the photoelectric conversion means, and having different positions of the center of gravity from each other. At least one opening is selected as the first opening, and at least one opening having a center of gravity different from the first opening is selected as the second opening, and the first and second openings are defined as the first opening. Based on an image signal based on the image of the subject formed on the photoelectric conversion means by the pupil dividing means that opens and closes the light flux in a time-sharing manner.Finding the amount of image displacementIn the camera with a focus detection device including a focus detection unit for detecting a focus state of the photographing optical system, the pupil division unit is a reverse polymer dispersion type liquid crystal by a pair of plate-like transparent members having a transparent electrode. And a reflection means for reflecting the light beam to the observation optical system or the focus detection means.When focus detection is performed at a position off the optical axis of the imaging optical system on the imaging plane, the imaging aperture of the imaging optical system and the outer shape of the lens of the imaging optical system are symmetrical with respect to the center of the overlapping portion. , Openings arranged in the detection direction of the image shift amount by the focus detection means are selected as the first and second openings.It is characterized by that.
[0016]
  According to a second invention, in the first invention,The reflecting means is provided on the front or rear surface of the pupil dividing means, and reflects the light beam to the observation optical system or the focus detecting means, respectively.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
(Explanation of focus detection principle)
First, the principle of focus detection will be described with reference to the drawings. 1 to 4 are schematic diagrams for explaining the principle of focus detection by the pupil time-division type image shift detection method.
[0022]
FIG. 1 is an explanatory diagram showing two apertures 202 and 203 and photoelectric conversion means 204 provided at an exit pupil position 201 of the imaging optical system. As shown in the figure, the exit pupil position 201 is provided with a pair of openings 202 and 203 with the optical axis 205 interposed therebetween. Here, the positions of the centers of gravity of the openings 202 and 203 are different from each other, and the openings 202 and 203 are not provided at the same position. Further, the photoelectric conversion means 204 is disposed on the planned imaging plane of the imaging optical system.
[0023]
2 to 4 are cross-sectional explanatory views when the imaging optical system shown in FIG. 1 is viewed from above. In the following description, the subject is described as a point light source (not shown) on the optical axis 205 of the imaging optical system.
FIGS. 2A and 2B are diagrams showing a state in which the imaging optical system is in focus. As shown in the drawing, each light beam from the point light source that passes through the opening 202 and the opening 203 forms an image at the same position A on the photoelectric conversion means 204.
[0024]
FIGS. 3A and 3B are diagrams showing a front pin state in which the focal position of the imaging optical system is present at a position before the in-focus position. As shown in FIG. 3A, the light beam from the point light source that passes through the opening 202 forms an image at a position B on the photoelectric conversion means 204. On the other hand, as shown in FIG. 3B, the light beam from the point light source that passes through the opening 203 forms an image at a position C on the photoelectric conversion means 204.
[0025]
FIGS. 4A and 4B are diagrams illustrating a rear pin state in which the focal position of the imaging optical system is present behind the in-focus position. As shown in FIG. 4A, the light beam from the point light source that passes through the opening 202 forms an image at a position D on the photoelectric conversion means 204. On the other hand, as shown in FIG. 4B, the light beam from the point light source passing through the opening 203 forms an image at a position E on the photoelectric conversion means 204.
[0026]
As described above, the image position on the photoelectric conversion means 204 changes according to the focus state of the imaging optical system. Accordingly, the openings 202 and 203 are set on the exit pupil position 201 of the imaging optical system, the portions other than the openings 202 and 203 provided at the exit pupil position 201 are shielded, and the openings 202 and 203 are alternately alternated in time. The positional relationship between the image signal captured by the photoelectric conversion means 204 when the opening 202 is opened and the image signal captured by the photoelectric conversion means 204 when the opening 203 is opened (image displacement direction and displacement amount). ) Is detected, it is possible to detect the focus state and focus shift amount (hereinafter referred to as defocus amount) of the imaging optical system.
[0027]
(Embodiment)
<Configuration of the embodiment>
FIG. 5 is an explanatory diagram showing a schematic configuration of an embodiment when the focus detection apparatus of the present invention is applied to a single-lens reflex camera. As shown in FIG. 5, the single-lens reflex camera is composed of a camera body 1 and an interchangeable lens structure 2.
[0028]
As shown in the figure, the interchangeable lens structure 2 provides information regarding the photographing optical system 20, the pupil dividing unit 3 disposed near the exit pupil position of the photographing optical system 20, and information regarding the photographing optical system 20 and the pupil dividing unit 3. And information means 21 for outputting. In the embodiment shown in FIG. 5, the pupil dividing means 3 is arranged in the optical path of the photographing optical system 20.
Further, as shown in the figure, the camera body 1 includes a pentaprism 10, a shutter 11, a film 12, a main mirror 13 that divides a light beam from the photographing optical system 20 into the pentaprism 10 and the shutter 11, and a main mirror 13. Of the sub-mirror 14 that deflects the light beam that has passed through the camera body 1 further to the bottom of the camera body 1, the photoelectric conversion means 4 that receives the light beam deflected by the sub-mirror 14, the pupil dividing means 3, and the photoelectric conversion means 4. Controls the operation, receives a signal from the photoelectric conversion means 4, calculates an image shift amount based on the signal, and based on the calculated image shift amount and information from the information means 21, Computation control means 5 for detecting a defocus amount (defocus amount).
[0029]
In the above configuration, the pupil dividing unit 3 has a configuration in which a pair of apertures arranged in the optical path near the exit pupil of the photographing optical system 20 are alternately shielded by time division under the control of the arithmetic control unit 5. Moreover, the photoelectric conversion means 4 is arrange | positioned in the vicinity of the surface optically conjugate with the surface where the film 12 is arrange | positioned.
The observation of the subject image is possible by the light beam passing through the pentaprism 10. The camera body 1 and the interchangeable lens structure 2 can be attached / detached.
[0030]
The pupil dividing unit 3 and the information unit 21 communicate with the calculation control unit 5 via the mounting unit (mount unit) when the camera body 1 and the interchangeable lens structure 2 are mounted.
The information means 21 generates the following information regarding the photographing optical system 20.
Focal length
Aberration information (spherical aberration, curvature of field information, etc.)
Information on the vignetting of the photographic beam (information on the outer shape / position of each lens, the outer shape / position of the aperture and hood, etc.)
The information means 21 generates the following information regarding the pupil dividing means 3.
Aperture shape, position in the optical axis direction, position in the exit pupil plane
Opening / closing state of opening
[0031]
<Operation of the embodiment>
The pupil dividing means 3 is in the fully open state before being activated by an operating member (not shown) (camera main switch or the like). Therefore, the photographer can observe the subject through the pentaprism 10.
[0032]
Next, when the calculation control means 5 is activated by an operation member (not shown), the calculation control means 5 shields light other than the opening of the pupil division means 3 and opens and closes the pair of openings alternately in a time division manner. The photoelectric conversion means 4 outputs an image signal when one opening is opened and an image signal when the other opening is opened in synchronization with opening and closing of the pair of openings alternately in a time division manner. .
[0033]
The arithmetic control means 5 performs an image shift detection calculation based on a well-known correlation operation on the two image signals, and calculates an image shift amount that is a relative positional shift between the two image signals.
Further, the arithmetic control unit 5 converts the image shift amount into a defocus amount in the optical axis direction in accordance with information on the shape of the opening, the optical axis direction, the position in the exit pupil plane, and the like from the information unit 21. . Further, the arithmetic control unit 5 corrects the defocus amount in accordance with the information regarding the aberration of the photographing optical system from the information unit 21, and calculates the final defocus amount.
[0034]
  That is, the arithmetic control means 51It has the role of the focus detection means described.
  Depending on the defocus amount finally calculated by the arithmetic control means 5, the photographing optical system 20 is driven in the direction of the optical axis by an actuator (not shown) (built in the camera body 1 or the interchangeable lens structure 2) to automatically adjust the focus. Alternatively, the defocus state may be displayed by display means (not shown).
  In the embodiment described above, the calculation control means 5 may be built in the interchangeable lens structure 2.
[0035]
<Configuration of pupil division means 3>
FIG. 6 is a diagram showing a specific example in which the pupil dividing means 3 is configured using a liquid crystal shutter. FIG. 6 is a view of the pupil dividing means 3 viewed from the optical axis direction. As shown in the figure, concentric regions 41, 42, 43 centered on the optical axis and a pair of openings 44, 45 are constituted by a liquid crystal shutter. Each area | region 41,42,43 and opening 44,45 are the structures which can apply a voltage independently.
The concentric regions 41, 42, and 43 are obtained by configuring the photographing aperture with a liquid crystal shutter. Therefore, in this example, the pupil dividing means 3 and the photographing aperture are also used. According to this configuration, the number of parts can be reduced.
[0036]
<Operation of pupil division means 3>
FIGS. 7A and 7B are views showing the operation of the pupil dividing means 3. As shown in the figure, by applying a voltage to the region other than the opening 44 or the opening 45, as shown in FIGS. 7A and 7B, the region other than the opening 44 or the opening 45 is set in a light-shielding state. Only 44 or the opening 45 can be made transparent.
[0037]
In the case of functioning as a photographing diaphragm, a voltage may be applied to a region outside a desired diaphragm outer diameter.
In the above configuration, since the pupil dividing means 3 is in a transparent state when no power is supplied, observation with a viewfinder is possible even when the power is off, and there is an advantage when used as a single-lens reflex camera.
[0038]
<Configuration of liquid crystal shutter>
FIGS. 8A and 8B are diagrams showing specific examples of liquid crystals used for the liquid crystal shutters constituting the pupil dividing means 3. FIGS. 8A and 8B show an example in which the pupil dividing means 3 is constituted by a liquid crystal shutter using a polymer dispersion type liquid crystal.
8A and 8B, the liquid crystal grains 38 dispersed in the polymer are sandwiched between the glass substrates 31, and a transparent electrode 32 is formed on the inner surface of the glass substrate 31, and a power source 35 and a switch 36 are formed. Thus, a voltage is applied to the transparent electrode 32.
[0039]
<Operation of liquid crystal shutter>
As shown in FIG. 8A, when no voltage is applied between the transparent electrodes 32, the liquid crystal molecules are aligned in different directions in the liquid crystal grains 38 dispersed in the polymer. Therefore, scattering occurs at the interface between the liquid crystal grains 38 and the polymer due to the difference in refractive index between the liquid crystal grains 38 and the polymer, and the incident light is shielded.
[0040]
As shown in FIG. 8B, when a voltage is applied between the transparent electrodes 32, the orientation directions of the liquid crystal molecules are aligned in the liquid crystal grains 38 dispersed in the polymer, and the refractive index of the liquid crystal and the polymer is high. Since they are equal, the incident light passes through without being scattered.
The advantage of configuring the pupil dividing means 3 using polymer dispersed liquid crystal is that the transmittance of the luminous flux is improved as compared with the case of using TN liquid crystal or GH liquid crystal because no polarizing plate or pigment is used.
[0041]
Further, the rise and fall characteristics when the voltage is on and off are superior to those of the TN liquid crystal and the GH liquid crystal, and a high-speed pupil division operation (opening / closing operation) is possible.
Further, when pupil division means is created using TN liquid crystal or GH liquid crystal, a step of aligning the liquid crystal with respect to the glass substrate is necessary. However, in the case where the pupil dividing means is created using the polymer dispersed liquid crystal, the above process is not required, so that the number of assembling steps can be reduced and the cost can be reduced.
[0042]
In the case of the liquid crystal shutter using the polymer dispersed liquid crystal shown in FIG. 8, the light is transmitted when a voltage is applied, and the light is blocked when a voltage is not applied. However, by using a reverse type polymer dispersed liquid crystal, a light shielding state is obtained when a voltage is applied, and a light transmitting state can be obtained when no voltage is applied.
For example, the reverse polymer dispersion type liquid crystal disclosed in the following document is in a translucent state when the voltage is not applied, and the refractive index of the liquid crystal and the polymer is different when the voltage is applied. Thus, it is configured to be in a light shielding state.
[0043]
Rumiko Yamaguchi et al.
Jpn. J. et al. Appl. Phys. Vo 1.36 (1998) pp. 2771-2774
Part 1, no. 5A. May, 1997
Reverse Mode and Wide View Angle Angle
Properties in Polymer Dispersed
Liquid Cells Prepared Using a UV
Curable Liquid Crystal
(Lumiko Yamaguchi et al., JP N.J.P.P.L.P.E.H.Y.S.V.B.O.L.36 (1998) pp. 2771-2774 Part 1, Number 5A Mei, 1997
Reverse Mode and Wide Viewing Angle Properties in Polymer Dispersed Liquid Cells Prepared Using A U Buoyable Liquid Crystal)
Advantages when the liquid crystal shutter (pupil dividing means) is constituted by the reverse polymer dispersed liquid crystal include the following matters.
[0044]
That is, the reverse polymer dispersed liquid crystal transmits light when no voltage is applied, so that when applied to a camera or the like, it can be observed with a finder or the like even when the power is turned off. In particular, since the reverse polymer dispersion type liquid crystal does not use a polarizing plate or a dye molecule, the light transmittance is improved as compared with the case where a TN liquid crystal or a GH liquid crystal is used, and observation with a bright screen becomes possible.
[0045]
In addition, since the liquid crystal shutter configured using the reverse type polymer dispersed liquid crystal has a high luminous flux transmittance, high-speed operation for focus detection is possible.
In addition, the reverse polymer dispersion type liquid crystal has a rising and falling characteristic when the voltage is on and off, which is superior to that of the TN liquid crystal and the GH liquid crystal, and enables high-speed pupil division operation (opening / closing operation).
Further, when pupil division means is created using TN liquid crystal or GH liquid crystal, a step of aligning the liquid crystal with respect to the glass substrate is necessary. However, in the case where the pupil dividing means is created using the polymer dispersed liquid crystal, the above process is not required, so that the number of assembling steps can be reduced and the cost can be reduced.
[0046]
<Configuration of photoelectric conversion means 4>
FIG. 9 is an explanatory view showing an example in which the photoelectric conversion means 4 is constituted by a two-dimensional CCD sensor. As shown in the figure, the photoelectric conversion means 4 has a configuration in which photoelectric conversion pixels 51 are two-dimensionally arranged. By disposing a two-dimensional CCD sensor as the photoelectric conversion means 4, it becomes possible to two-dimensionally detect the focus state of the photographing optical system 20.
[0047]
Further, as shown in FIG. 9, by arbitrarily selecting photoelectric conversion pixels 51 used for focus detection calculation described later as areas 46, 47, and 48, the areas 46, 47, and 48 are displayed on the photographing screen. It becomes possible to detect the focus state at the corresponding position.
[0048]
FIG. 10 is a partially enlarged view of the two-dimensional CCD sensor shown in FIG. As shown in the drawing, the CCD sensor includes a photoelectric conversion pixel 51, a pair of gates 52 and 53, a pair of charge storage units 54 and 55, a gate 56, and a CCD charge transfer unit 57.
Since the conventional CCD sensor has only one charge accumulating unit for one photoelectric conversion pixel, when the aperture of the pupil dividing means 3 is switched, the previous accumulated charge is used each time to capture the next image. It is necessary to output to the outside as an electrical signal.
[0049]
According to the CCD sensor shown in FIG. 10, a pair of gates 52 and 53 and a pair of charge storage units 54 and 55 are provided for one photoelectric conversion pixel 51. Therefore, when the aperture is switched, the charges corresponding to the image of the subject formed by the different apertures can be stored in the separate charge storage portions 54 and 55 by simply switching the gates 52 and 53.
Then, it is only necessary to transfer the charge and output it externally after the accumulation is completed, so that it is possible to cope even when the aperture is switched at high speed.
Further, by using a two-dimensional CCD sensor, it is possible to detect a focus at an arbitrary position in the photographing screen.
[0050]
<Operation of photoelectric conversion means 4>
In FIG. 10, the photoelectric conversion pixel 51 generates an electric charge according to the amount of incident light. The gates 52 and 53 are closed before charge accumulation, and the generated charges are discarded to a drain (not shown). The gates 52 and 53 open and close alternately during charge accumulation. Therefore, charges generated in the photoelectric conversion pixel 51 while the gate 52 is open are stored in the charge storage unit 54, and charges generated in the photoelectric conversion pixel 51 while the gate 53 is open are stored in the charge storage unit 55. Is done. During this time, the gate 56 is closed.
[0051]
When the charge accumulation is completed, the gates 52 and 53 are closed, and then the gate 56 is opened, whereby the charges accumulated in the charge accumulation unit 54 and the charge accumulation unit 55 move to the CCD charge transfer unit 57. Thereafter, the charges transferred to the CCD charge transfer unit 57 are transferred according to the operation clock of the CCD and output to the outside as an electric signal.
[0052]
<Synchronized operation of aperture switching and charge accumulation>
FIG. 11 is a diagram illustrating operation timings of opening switching and charge accumulation. FIG. 11C shows a period during which the opening 44 shown in FIG. 6 performs an opening / closing operation. Therefore, charges are accumulated in the charge accumulation unit 54 shown in FIG. 10 over this period.
FIG. 11D shows a period in which the opening 45 shown in FIG. 6 performs an opening / closing operation. Therefore, charges are accumulated in the charge accumulation unit 55 shown in FIG. 10 over this period.
FIG. 11A is a diagram showing details of FIG. 11C. As shown in FIG. 11A, the opening 44 shown in FIG. 6 is repeatedly opened and closed during the on period and closed during the off period. This signal is applied to the gate 52.
[0053]
FIG. 11B is a diagram showing details of FIG. 11D. As shown in FIG. 11B, the opening 45 shown in FIG. 6 is repeatedly opened and closed during the on period and closed during the off period. This signal is applied to the gate 53.
FIG. 11E is a diagram illustrating a charge transfer period after the charge accumulation of the charge accumulation units 54 and 55 is completed.
[0054]
The signal waveform shown in (a) of FIG. 11 and the signal waveform shown in (b) of FIG. 11 are in an opposite phase relationship, and are repeatedly turned on / off. That is, the signal waveform shown in FIG. 11A is applied from the arithmetic control means 5 to the opening 44 shown in FIG. 6 and to the gate 52 shown in FIG.
The signal waveform shown in (b) of FIG. 11 is applied from the arithmetic control means 5 to the opening 45 shown in FIG. 6 and to the gate 53 shown in FIG.
[0055]
Accordingly, the opening 44 and the opening 45 are alternately opened and closed alternately, and the charge photoelectrically converted during the period in which the opening 44 is open is accumulated in the charge storage unit 54 and is photoelectrically converted during the period in which the opening 45 is open. The charge is accumulated in the charge accumulation unit 55.
In FIG. 6, regions 41, 42, and 43 other than the openings 44 and 45 are applied with an on signal during the operation period of the openings 44 and 45, and are applied with an off signal during other periods. In this way, the pupil dividing means 3 is fully open except during the operation period of the openings 44 and 45. Therefore, it is possible to observe the image of the subject with the viewfinder, which is advantageous when used as a single-lens reflex camera.
[0056]
It is also conceivable to store charges by switching the opening 44 and the opening 45 only once. However, in this case, there is a possibility that the difference between the charge accumulation amounts due to the two openings becomes large. In other words, regarding the calculation of the amount of image shift due to the movement of the subject in the optical axis direction and the direction perpendicular to the optical axis direction generated during charge accumulation by the two openings, or the movement of the subject image on the image plane due to camera shake, There is a possibility that the amount of error cannot be ignored.
As in the embodiment of the present invention, by alternately repeating the switching of the opening and the charge accumulation, there is an advantage that the deviation of the charge accumulation amount can be reduced.
[0057]
<Calculation processing of calculation control means 5>
The electric signal output from the photoelectric conversion means 4 is AD-converted into digital data by the arithmetic control means 5, and the amount of image shift is calculated based on the obtained digital data. Basically, the data Ai (i = 1 to n) corresponding to the subject image formed by the opening 44 and the data Bi (i = 1 to n) corresponding to the subject image formed by the opening 45 are relatively compared. Correlation calculation is performed while shifting, and an image shift amount between two images is calculated from a relative shift amount having a high degree of correlation.
[0058]
Since the relative shift amount can actually take only an integer value, a value equal to or less than the integer value of the image shift amount is obtained by interpolation.
As a correlation calculation method, there are a first method for calculating the sum of absolute values of differences between data and a second method for calculating the sum of multiplications between data.
[0059]
The first method is advantageous in that the smaller the total amount is, the higher the degree of correlation is, and the calculation time can be shortened, and there is a demerit that an error is large when there is crosstalk or offset between data.
The second method indicates that the larger the total amount is, the higher the degree of correlation is, and there is a demerit that calculation time is required, but there is an advantage that an error is small even when there is an offset between data.
[0060]
Switching the aperture actually requires a transition time. Therefore, the obtained data often has a crosstalk component with each other. The ratio of the crosstalk component of the data can be corrected by arithmetic processing by determining it beforehand by experiment or by measuring it individually during assembly. Next, a correction method will be described.
Data Ai = αi + bi (1)
Data Bi = βi + ai (2)
However,
αi is the effective component included in the data Ai
bi is a crosstalk component included in data Ai
βi is the effective component included in data Bi
ai is a crosstalk component included in the data Bi.
[0061]
Assuming that the crosstalk ratio K = (ratio of ai to αi) = (ratio of bi to βi), the data of only the effective component not including the crosstalk component can be obtained by correcting the data based on the following equation. .
Data A′i = Ai−K × Bi = αi−K × ai (3)
Data B′i = Bi−K × Ai = βi−K × bi (4)
If the correlation calculation is performed while the corrected data A′i and B′i are relatively shifted, the image shift amount L between the two images from which the influence of the crosstalk has been removed can be calculated.
[0062]
The crosstalk ratio K changes in relation to the characteristics of the pupil dividing unit 3 (frequency characteristics and temperature characteristics of aperture switching), the characteristics (frequency characteristics, temperature characteristics, etc.) of the photoelectric conversion unit 4 and the focus detection position. Characteristic information of the pupil dividing means 3 obtained from the information means 21 by the arithmetic control means 5 and characteristics and operating environment parameters (temperature, drive frequency, accumulation time, etc.) of the photoelectric conversion means 4 stored in advance by the arithmetic control means 5 and The crosstalk ratio K is calculated based on the focus detection condition (focus detection position or the like).
[0063]
Further, when the focus detection position is not on the optical axis, the light flux reaching the focus detection position becomes asymmetric. Therefore, the crosstalk ratio K is also different from the data A′i and B′i. , K2 is set.
Data A′i = Ai−K1 × Bi = αi−K1 × ai (5)
Data B′i = Bi−K2 × Ai = βi−K2 × bi (6)
When a two-dimensional CCD sensor is used as the photoelectric conversion means 4, the data used for the calculation is, for example, data in the areas 46, 47, and 48 in FIG.
[0064]
Next, the image shift amount L (x, y) is converted into a focus shift amount in the optical axis direction = defocus amount D (x, y). Here, x and y are parameters for designating the focus detection position in two dimensions. Here, the conversion coefficient is S (x, y).
D (x, y) = S (x, y) × L (x, y) (7)
The conversion coefficient S (x, y) is a characteristic of the pupil dividing means 3 (aperture shape, aperture position in the pupil plane, position in the optical axis direction) and characteristics of the photographing optical system 20 (external shape / position of each lens, aperture, etc. It changes in relation to the outer shape / position of the hood) and the focus detection position. Therefore, the conversion coefficient S (x, y) is obtained from the characteristic information of the pupil dividing means 3 obtained from the information means 21, the characteristic information of the photographing optical system 20, and the focus detection position information set by the arithmetic control means 5 or the photographer. Is calculated by the calculation control means 5 based on the above.
[0065]
The correction amount C (x, y) is added to the defocus amount D (x, y) calculated by the equation (7) to calculate the correction defocus amount D ′ (x, y).
D '(x, y) = D (x, y) + C (x, y) (8)
The correction amount C (x, y) is a characteristic of the pupil dividing means 3 (aperture shape, aperture position in the pupil plane, position in the optical axis direction) and characteristics of the photographing optical system 20 (external shape / position of each lens, aperture) And the shape and position of the hood, aberration, etc.) and the focus detection position. Therefore,
The correction amount C (x, y) is based on the characteristic information of the pupil dividing means 3 obtained from the information means 21, the characteristic information of the photographing optical system 20, and the focus detection position information set by the arithmetic control means 5 or the photographer. The calculation is performed by the calculation control means 5.
[0066]
When focus detection is performed at one designated position, focus adjustment drive of the imaging optical system 20 is performed based on the corrected defocus amount D ′ (x, y) obtained by Expression (8), The focus adjustment status is displayed.
When focus detection is performed at a plurality of positions, based on a plurality of correction defocus amounts D ′ (x, y) corresponding to the plurality of locations, a correction defocus amount that indicates the closest distance among them is selected, The final defocus amount is calculated by calculating the average defocus amount of the defocus amounts. Then, based on the final defocus amount, the focus adjustment drive of the photographing optical system 20 is performed, or the focus adjustment state is displayed.
[0067]
(Variation of the embodiment)
FIG. 12 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 5 (one embodiment when the focus detection apparatus according to the present invention is applied to a single-lens reflex camera). The difference between the embodiment shown in FIG. 5 and the embodiment shown in FIG. 12 is that the pupil dividing means 3 is not built in the interchangeable lens structure 2 but is built in the camera body 1. . The pupil dividing means 3 is arranged in the optical path between the photographing optical system 20 and the main mirror 13.
[0068]
The advantage of the embodiment shown in FIG. 12 is that the position of the pupil dividing means 3 is constant without depending on the type of the interchangeable lens structure 2, and the focus detection accuracy is stable.
Further, since the pupil dividing means 3 is not built in the interchangeable lens structure 2, the cost of the interchangeable lens can be reduced.
In addition, since the pupil dividing means 3 is not built in the interchangeable lens structure 2, focus detection is possible even with a conventional interchangeable lens.
[0069]
In addition, since the pupil dividing means 3 and the calculation control means 5 are built in the camera body 1, the pupil dividing means 3 and the calculation control means 5 are fixed, so the pupil dividing means 3 is built in the interchangeable lens structure 2. The complexity of the control operation can be eliminated as compared with the case where the pupil division means 3 is optimized.
Specifically, when the pupil dividing means 3 is provided in the interchangeable lens structure 2, it is difficult to match a large number of pupil dividing means 3 and arithmetic control means 5 having different characteristics. However, the provision of the pupil dividing means 3 in the camera body 1 has an advantage that adjustment at the time of assembly and the like is facilitated because only matching between one pupil dividing means and the arithmetic control means 5 has to be considered. When the pupil dividing means 3 is provided in the interchangeable lens structure 2, it is necessary to store information related to the pupil dividing means 3 in the information means 21. However, providing the pupil dividing means 3 in the camera body 1 eliminates the need for the information means 21 to store information relating to the pupil dividing means 3.
[0070]
In the embodiment shown in FIG. 12, a photometric means 27 is disposed in the vicinity of the eyepiece surface of the pentaprism 10, and the luminance of the subject is measured through the photographing optical system 20. However, even if the photometry unit 27 performs photometry during the operation of the pupil division unit 3 (during the on period shown in (c) and (d) of FIG. 11), the pupil division unit 3 limits the luminous flux. Therefore, accurate metering is not possible. Therefore, when the pupil dividing unit 3 is operating, the arithmetic control unit 5 prohibits the photometric operation by the photometric unit 27.
[0071]
When the light metering means 27 unavoidably performs photometry during the operation of the pupil splitting means 3 (during the ON period of (c) and (d) in FIG. 11), the measured luminance is the amount of light limited by the pupil splitting means 3. Correct by minutes. For example, the photometric means 27 corrects based on the area ratio or the like when the opening 44 or 45 shown in FIG. 6 is in the transmissive state and when all the regions 41 to 45 are in the transmissive state.
[0072]
The photometric correction amount includes the characteristics of the pupil dividing means 3 (aperture shape, aperture position in the pupil plane, position in the optical axis direction) and the characteristics of the photographing optical system 20 (external shape / position of each lens, external shape / diaphragm of the aperture or hood) Position, aberration, etc.) and the configuration and arrangement of the photometric means 27 or the configuration of the finder optical system. Therefore, the photometric means 27 calculates based on the characteristic information of the pupil dividing means 3 obtained from the information means 21, the characteristic information of the photographing optical system 20, and the information relating to the photometric system possessed by the photometric means 27 itself.
[0073]
In particular, when a later-described polymer dispersed liquid crystal is used as the pupil dividing means 3, it cannot be completely shielded even in a light-shielded state, and a scattered light component exists. Therefore, it is necessary to ensure sufficient matching with the characteristics of the pupil dividing means 3 (such as luminance at the time of light shielding).
In such a case, if the pupil dividing means 3 and the photometric means 27 are incorporated on the camera body 1 side, the data relating to the photometric correction is adjusted individually for each camera body 1 at the time of assembling. It is also possible to deal with individual variations in characteristics.
[0074]
FIG. 13 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. The difference between the embodiment shown in FIG. 12 and the embodiment shown in FIG. 13 is that the pupil dividing means 3 also functions as the main mirror. A translucent film is formed on the surface of the pupil dividing means 3 so that a part of the incident light beam is reflected to the pentaprism 10.
[0075]
The advantage of the embodiment shown in FIG. 13 is that the pupil dividing means 3 also functions as the main mirror, thereby reducing the number of parts and reducing the cost.
In addition, space efficiency is high compared to the case where the pupil dividing means 3 is separately arranged, and the camera body 1 can be downsized.
The main mirror 13 and the pupil dividing means 3 may be used as a configuration in which the main mirror 13 is provided and the pupil dividing means 3 made of liquid crystal is arranged on the back side (shutter 11 side).
[0076]
FIG. 14 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 12 is that the pupil dividing means 3 also functions as a submirror. A translucent film is formed on the rear surface of the pupil dividing means 3 so that only the light beam that has passed through the pupil dividing means 3 is reflected in the direction of the photoelectric conversion means 4.
[0077]
The advantage of the embodiment shown in FIG. 14 is that the pupil dividing means 3 also serves as a sub-mirror function, thereby reducing the number of parts and reducing the cost.
Further, the space efficiency is high and the size of the camera body 1 can be reduced as compared with the case where the pupil dividing means 3 and the sub mirror are separately arranged.
In addition, as a configuration in which the pupil dividing unit 3 and the sub mirror are used together, a sub mirror may be provided and the pupil dividing unit 3 made of liquid crystal may be provided on the front surface of the sub mirror.
[0078]
FIG. 15 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 12 is that the pupil dividing means 3 is not in the optical path to the primary image plane (the surface of the film 12), but the relay optical system (condenser lens 22, pupil dividing means 3, reconnection). This is a point arranged in the optical path of the re-imaging optical system (consisting of the image lens 23 and the like).
[0079]
In FIG. 15, the condenser lens 22 is disposed in the optical path folded by the sub mirror 14. The pupil dividing means 3 is disposed on the front surface or the rear surface of the re-imaging lens 23. Further, the photoelectric conversion means 4 is disposed in the vicinity of the secondary image plane by the re-imaging lens 23.
The advantage of the embodiment shown in FIG. 15 is that the pupil division means 3 is not present in the photographing optical path or the observation optical path, so that it is possible to prevent the light amount and image quality from being lowered.
[0080]
Further, since the pupil dividing means 3 is arranged in the re-imaging optical system having a narrow optical path, the pupil dividing means 3 can be downsized as compared with the case where it is arranged in the photographing optical path.
FIG. 16 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 15 is that the relay optical system is arranged not in the optical path passing through the main mirror 13 and the sub mirror 14 but in the observation optical system reflected by the main mirror 13. .
[0081]
In FIG. 16, the lower surface 24 of the pentaprism 10 has a condenser lens function. The roof surface 25 of the pentaprism 10 is translucent, and the re-imaging lens 23 is provided in the optical path that has passed through the roof surface 25. The pupil dividing means 3 is arranged on the front surface or the rear surface of the re-imaging lens 23 (arranged on the front surface in the example of FIG. 16), and the photoelectric conversion means 4 is arranged near the secondary image surface by the re-imaging lens 23. Has been.
[0082]
The advantage of the embodiment shown in FIG. 16 is that the pupil division means 3 is not present in the photographing optical path, so that it is possible to prevent a reduction in photographing light quantity and image quality.
Further, since the pupil dividing means 3 is arranged in the re-imaging optical system having a narrow optical path, the pupil dividing means 3 can be downsized.
Further, since the re-imaging optical system is arranged in the observation optical system, the main mirror 13 may be a simple reflection mirror, and a sub mirror is not necessary.
[0083]
FIG. 17 is an explanatory diagram showing a schematic configuration of an embodiment when the focus detection apparatus according to the present invention is applied to an electronic finder type silver salt camera.
As shown in FIG. 17, this electronic viewfinder type silver salt camera is composed of a camera body 1 and an interchangeable lens structure 2.
As shown in the figure, the interchangeable lens structure 2 provides information regarding the photographing optical system 20, the pupil dividing unit 3 disposed near the exit pupil position of the photographing optical system 20, and information regarding the photographing optical system 20 and the pupil dividing unit 3. And information means 21 for outputting. In the embodiment shown in FIG. 17, the pupil dividing means 3 is arranged in the optical path of the photographing optical system 20.
[0084]
Further, as shown in the figure, the camera body 1 is a mirror that polarizes the light beam from the shutter 11, the film 12, and the photographing optical system 20, and a main mirror 13 that retracts from the photographing optical path during photographing, and the main mirror 13 A photoelectric conversion means 4 comprising a reduction optical system 17 for reducing the image of the light beam that has passed through, a two-dimensional CCD sensor disposed on the image plane of the reduction optical system 17, the pupil dividing means 3 and the photoelectric conversion means. 4, receives a signal from the photoelectric conversion means 4, calculates an image shift amount based on the signal, and based on the calculated image shift amount and information from the information means 21, a photographing optical system A calculation means 5 for detecting the amount of defocus of 20; a display means 18 constituted by a liquid crystal or the like for displaying the signal of the photoelectric conversion means 4 taken into the calculation control means 5 as an image; And a a provided an observation optical system 19. In order to observe the display screen of the Display device 18.
[0085]
The advantage of the embodiment shown in FIG. 17 is that since the photoelectric conversion means 4 receives the image of the reduction optical system 17, an area sensor having a small area is used as the photoelectric conversion means 4 compared to the image sensor used in the electronic camera. It can be used.
Further, the output signal of the photoelectric conversion means 4 can be used not only for focus detection but also as an image signal for display on the display means 18.
[0086]
Further, since the electronic viewfinder is adopted as compared with the optical viewfinder shown in FIG. 5, the camera body 1 can be downsized.
Further, the main mirror 13 may be a simple reflection mirror, and a sub mirror is unnecessary.
FIG. 18 is an explanatory diagram showing a schematic configuration when the embodiment shown in FIG. 17 is applied to an electronic camera. The difference from the embodiment shown in FIG. 17 is that an imaging means 15 and a storage means 16 for storing an image signal output from the imaging means 15 are provided instead of the shutter 11 and the film 12. .
[0087]
The advantage of the embodiment shown in FIG. 18 is that since the photoelectric conversion means 4 receives the image of the reduction optical system 17, an area sensor having a smaller area than that of the imaging means 15 can be used.
Further, the main mirror 13 can be used as a shutter for the image pickup means 15.
[0088]
In addition, the output signal of the photoelectric conversion means 4 for focus detection can be used as an image signal for display.
Further, since the image pickup means 15 is not used for image display, it is not necessary to always drive the image pickup means 15 having a larger number of pixels compared to the photoelectric conversion means 4 and power consumption can be reduced.
[0089]
FIG. 19 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG.
The difference from the embodiment shown in FIG. 18 is that the signal of the imaging means 15 taken into the storage means 16 is displayed as an image by the display means 18 and observed by the observation optical system 19. Further, the main mirror 13 is a half mirror, and it is not necessary to escape from the optical path during shooting.
[0090]
The advantage of the embodiment shown in FIG. 19 is that a high-quality screen can be observed because the observation optical system 19 observes the signal of the imaging means 15 as a display screen.
Further, since a mechanism for retracting the main mirror 13 is not required, the camera mechanism can be simplified.
FIG. 20 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 19 is that the pupil dividing means 3 is built in the camera body 1 instead of the interchangeable lens structure 2. That is, the embodiment shown in FIG. 20 is an electronic camera version of the embodiment shown in FIG.
[0091]
As shown in the figure, the pupil dividing means 3 is disposed in the optical path between the photographing optical system 20 and the main mirror 13 in the camera body 1. Further, the main mirror 13 is constituted by a half mirror, the imaging means 15 is disposed in the optical path deflected by the main mirror 13, and the photoelectric conversion means 4 receives the light beam that has passed through the main mirror 13.
[0092]
The advantage of the embodiment shown in FIG. 20 is that the position of the pupil dividing means 3 is constant regardless of the interchangeable lens, and the focus detection accuracy is stable.
Moreover, since it is not necessary to incorporate the pupil dividing means 3 for each interchangeable lens structure 2, the cost of the interchangeable lens can be reduced.
Further, since the pupil dividing means 3 is not built in the interchangeable lens structure 2, focus detection is possible even with a conventional interchangeable lens.
[0093]
In addition, since the pupil dividing means 3 and the calculation control means 5 are built in the camera body 1, the pupil dividing means 3 and the calculation control means 5 are fixed, so the pupil dividing means 3 is built in the interchangeable lens structure 2. The complexity of the control operation can be eliminated as compared with the case where the pupil division means 3 is optimized.
Specifically, when the pupil dividing means 3 is provided in the interchangeable lens structure 2, it is difficult to match a large number of pupil dividing means 3 and arithmetic control means 5 having different characteristics. However, the provision of the pupil dividing means 3 in the camera body 1 has an advantage that adjustment at the time of assembly and the like is facilitated because only matching between one pupil dividing means and the arithmetic control means 5 has to be considered. When the pupil dividing means 3 is provided in the interchangeable lens structure 2, it is necessary to store information related to the pupil dividing means 3 in the information means 21. However, providing the pupil dividing means 3 in the camera body 1 eliminates the need for the information means 21 to store information relating to the pupil dividing means 3.
[0094]
Further, if the main mirror 13 is retracted as a normal mirror, the main mirror 13 can also be used as a shutter of the imaging means 15.
FIG. 21 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. As shown in the figure, the difference from the embodiment shown in FIG. 19 is that the pupil dividing means 3 is built in the camera body 1 instead of the interchangeable lens structure 2.
[0095]
In FIG. 21, the signal of the imaging means 15 is taken into the storage means 16 and the signal is displayed as an image on the display means 18. This image is observed by the observation optical system 19. Further, the main mirror 13 is a half mirror, and it is not necessary to escape from the optical path during shooting.
[0096]
The advantage of the embodiment shown in FIG. 21 is that the position of the pupil dividing means 3 is constant regardless of the interchangeable lens structure 2, and the focus detection accuracy is stable.
Further, since it is not necessary for the interchangeable lens structure 2 to incorporate the pupil dividing means 3, the cost of the interchangeable lens structure 2 can be reduced.
Further, since the pupil dividing means 3 is not built in the interchangeable lens structure 2, focus detection is possible even with a conventional interchangeable lens.
[0097]
In addition, since the pupil dividing means 3 and the calculation control means 5 are built in the camera body 1, the pupil dividing means 3 and the calculation control means 5 are fixed, so the pupil dividing means 3 is built in the interchangeable lens structure 2. The complexity of the control operation can be eliminated as compared with the case where the pupil division means 3 is optimized.
Specifically, when the pupil dividing means 3 is provided in the interchangeable lens structure 2, it is difficult to match a large number of pupil dividing means 3 and arithmetic control means 5 having different characteristics. However, the provision of the pupil dividing means 3 in the camera body 1 has an advantage that adjustment at the time of assembly and the like is facilitated because only matching between one pupil dividing means and the arithmetic control means 5 has to be considered. When the pupil dividing means 3 is provided in the interchangeable lens structure 2, it is necessary to store information related to the pupil dividing means 3 in the information means 21. However, providing the pupil dividing means 3 in the camera body 1 eliminates the need for the information means 21 to store information relating to the pupil dividing means 3.
[0098]
In addition, since the signal output from the image pickup means 15 is displayed on the screen, high quality observation is possible.
Further, since a mechanism for retracting the main mirror 13 is not required, the camera mechanism can be simplified.
FIG. 22 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 21 is that the pupil dividing means 3 also functions as a main mirror.
[0099]
As shown in the figure, the pupil dividing means 3 includes a liquid crystal 3a having a plurality of openings in the vicinity of a position where a light beam from the photographing optical system is irradiated. In addition, a total transmission mirror 3b and a half mirror 3c are provided on the back surface of the pupil dividing means 3. The position where the half mirror 3c is provided corresponds to the position where the liquid crystal 3a is provided.
Since it has said structure, the light from the opening selectively controlled by the pupil division means 3 reaches | attains the photoelectric conversion means 4. FIG.
[0100]
The advantage of the embodiment shown in FIG. 22 is that the pupil dividing means 3 also serves as the main mirror function, thereby reducing the number of parts and reducing the cost.
In addition, space efficiency is high compared to the case where the pupil dividing means 3 is separately arranged, and the camera body 1 can be downsized.
FIG. 23 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 21 is that the pupil dividing means 3 is not in the optical path to the surface of the imaging means 15 but in the optical path of the re-imaging optical system by the relay optical system deflected by the main mirror 13. It is a point that is arranged. Here, the re-imaging optical system is an optical system including the re-imaging lens 23 and the condenser lens 22. The main mirror 13 is a half mirror.
[0101]
In FIG. 23, the condenser lens 22 is disposed in the vicinity of the primary image plane in the optical path deflected by the main mirror 13. The pupil dividing means 3 is disposed on the front surface or the rear surface of the re-imaging lens 23. Further, the photoelectric conversion means 4 is disposed in the vicinity of the secondary image plane by the re-imaging lens 23.
The advantage of the embodiment shown in FIG. 23 is that the pupil division means 3 does not exist in the photographing optical path, so that it is possible to prevent the light amount and the image quality from being lowered.
[0102]
Further, since the pupil dividing unit 3 is disposed in the re-imaging optical system, the pupil dividing unit 3 can be downsized.
FIG. 24 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. The difference from the embodiment shown in FIG. 23 is that the pupil dividing means 3, the photoelectric conversion means 4, and the calculation control means 5 are all built in the interchangeable lens structure 2. Moreover, the arithmetic control means 5 has the function of an information means (21).
[0103]
According to the embodiment shown in FIG. 24, the half mirror 26 is arranged in the middle of the photographing optical system 20, and a part of the photographing light beam is deflected. As shown in the figure, the pupil dividing means 3, the reduction optical system 17, and the photoelectric conversion means 4 are arranged in the optical path deflected by the half mirror 26. The photoelectric conversion means 4 is disposed on the image plane of the reduction optical system 17.
[0104]
The advantage of the embodiment shown in FIG. 24 is that the configuration used for focus detection (pupil division means 3, photoelectric conversion means 4, and calculation control means 5) is all built in the interchangeable lens assembly 2, so that the normal camera body It is possible to detect the focus even when it is attached to the camera.
FIG. 25 is an explanatory diagram showing a schematic configuration when the embodiment shown in FIG. 19 is applied to a lens-integrated electronic camera. The difference from the embodiment shown in FIG. 19 is that the photoelectric conversion means 4 for focus detection and the image pickup means (15) are combined.
[0105]
The operation of the photoelectric conversion means 4 is controlled by the arithmetic control means 5, and the output signal is sent to the arithmetic control means 5 and the storage means 16.
The advantage of the embodiment shown in FIG. 25 is that the cost of the system can be reduced by combining the photoelectric conversion means 4 for focus detection and the imaging means.
Further, by integrating the camera body and the lens, the photographing optical system can be specified, the configuration and operation of the pupil dividing unit 3 can be optimized, and more accurate focus detection can be performed.
[0106]
FIG. 26 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG.
The difference from the embodiment shown in FIG. 22 is that the photoelectric conversion means 4 and the image pickup means (15) are combined. The pupil dividing means 3 has a liquid crystal on its surface and reflects an image of an aperture that can be switched alternately to the photoelectric conversion means 4.
[0107]
The advantage of the embodiment shown in FIG. 26 is that the cost of the system can be reduced by combining the photoelectric conversion means 4 for focus detection and the imaging means.
Further, by arranging the photoelectric conversion means 4 in the optical path deflected by the pupil dividing means 3 and also using the imaging means, the size of the camera body 1 in the optical axis direction can be reduced, and the camera body can be downsized. It becomes.
[0108]
(Removing the effects of vignetting)
When focus detection is performed at a position outside the optical axis of the screen, vignetting occurs due to the outer diameter of the lens other than the diaphragm.
FIG. 27 is an explanatory diagram showing an example in which vignetting occurs due to the lens outer diameter of the photographing optical system. The optical system shown in FIG. 27 includes an imaging surface 60, an optical axis 61, a photographing aperture 62, and an outer diameter 63 of a lens constituting the photographing optical system.
[0109]
As shown in the figure, at a point 64 on the optical axis, vignetting of the light beam does not occur except for the photographing aperture 62. However, at the point 65 outside the optical axis, as shown in FIG. 28, vignetting due to vignetting of the light flux occurs. That is, in FIG. 28, only the light beam that passes through the portion 66 where the photographing diaphragm 62 and the outer diameter 63 of the lens constituting the shadow optical system overlap each other reaches the point 65 outside the optical axis shown in FIG.
[0110]
Therefore, when focus detection is performed at a point outside the optical axis, the light quantity of the pair of light beams used for focus detection is unbalanced by the vignetting just by switching the opening symmetrical to the optical axis. The focus detection accuracy deteriorates. If the vignetting is large, the light beam passing through one of the apertures is completely vignetted, making it impossible to detect the focus.
Next, the configuration and operation of the pupil dividing means 3 for preventing the influence of vignetting will be described with reference to FIGS.
[0111]
FIG. 29 is a diagram showing a first specific example of the pupil dividing means 3 for preventing the light quantity imbalance of a pair of light beams caused by vignetting. As shown in FIG. 29, the pupil dividing means 3 also serves as the photographing aperture 62. Further, the plurality of elliptical openings 67 are configured to be able to control light shielding and light transmission independently. The elliptical openings 67 are densely arranged on the pupil plane. In FIG. 29, the image shift detection direction for focus detection is set to an elliptical short axis direction (horizontal direction in the drawing).
[0112]
When the focus detection position is on the optical axis, symmetrical openings 68 and 69 on the optical axis of the pupil dividing means 3 are alternately switched as shown in FIG.
When the focus detection position is outside the optical axis (when vignetting occurs in the image shift detection direction), as shown in FIG. 31, the lines are symmetrically arranged with respect to the center of the overlapping portion 66 due to vignetting in the image shift detection direction. The openings 70 and 71 are alternately switched.
[0113]
Further, when the focus detection position is off the optical axis (when vignetting occurs in a direction perpendicular to the image shift detection direction), as shown in FIG. 32, the focus detection position is symmetrical with respect to the center of the overlapping portion 66 due to vignetting. The openings 72 and 73 aligned in the image shift detection direction are alternately switched.
Note that the state of vignetting is configured to be identified by the arithmetic control unit 5 based on information obtained from the information unit 21.
[0114]
The advantage of the pupil division means 3 shown in FIG. 29 is that the vignetting of the focus detection light beam is eliminated by switching and using a plurality of apertures according to the state of vignetting, and the focus detection accuracy is reduced and focus detection is caused by vignetting. It is to prevent it from becoming impossible.
FIG. 33 is a diagram showing a second specific example of the pupil dividing means 3 for preventing the light quantity imbalance between a pair of light beams caused by vignetting. As shown in FIG. 33, the pupil dividing means 3 also serves as the photographing aperture 62. Further, the plurality of hexagonal openings 74 are configured to be able to control light shielding and light transmission independently. The elliptical openings 74 are closely packed on the pupil plane. In FIG. 33, the image shift detection direction for focus detection is set to the horizontal direction.
[0115]
When the focus detection position is on the optical axis, it is symmetric with respect to the optical axis of the pupil dividing means 3, as shown in FIG. Therefore, as illustrated, the openings 75 and 76 formed from a plurality of openings are alternately switched.
When the focus detection position is outside the optical axis (when vignetting occurs in the image shift detection direction), the aperture is controlled as follows. That is, as shown in FIG. 35, openings 77 and 78 formed by a plurality of openings arranged symmetrically with respect to the center of the overlapping portion 66 due to vignetting and arranged in the image shift detection direction are alternately switched.
[0116]
When the focus detection position is off the optical axis (when vignetting occurs in a direction perpendicular to the image shift detection direction), the aperture is controlled as follows. That is, as shown in FIG. 36, openings 79 and 80 formed by a plurality of openings arranged symmetrically with respect to the center of the overlapping portion 66 due to vignetting and arranged in the image shift detection direction are alternately switched.
The advantage of the pupil division means 3 shown in FIG. 33 is that the vignetting of the focus detection light beam is eliminated by switching and using a plurality of apertures according to the state of vignetting, and the focus detection accuracy is lowered and the focus detection is reduced. It is to prevent it from becoming impossible.
[0117]
In addition, by adopting hexagonal openings, a plurality of openings can be efficiently arranged on the pupil plane.
Further, by forming an opening by combining a plurality of hexagonal openings, the opening shape can be set flexibly with respect to vignetting.
Moreover, the light quantity utilized for focus detection can be increased by forming an opening by combining a plurality of hexagonal openings. Therefore, the brightness that is the limit of focus detection can be set to a low value.
[0118]
FIG. 37 is a diagram showing a third specific example of the pupil dividing means 3 for preventing the light quantity imbalance of a pair of light beams caused by vignetting. As shown in FIG. 37, the pupil dividing means 3 also serves as the photographing aperture 62. Further, the plurality of square-shaped openings 81 are configured to be able to independently control light shielding and light transmission. The square-shaped openings 81 are densely arranged on the pupil plane. In FIG. 33, the image shift detection direction for focus detection is set to a horizontal direction, a vertical direction, a right 45 degree direction, and a left 45 degree direction (four directions).
[0119]
FIG. 38 is a diagram showing the configuration of the photoelectric conversion means 4 used in combination with the pupil dividing means 3 shown in FIG. As shown in FIG. 38, the shape of the pixel 92 is a square, and the pixel pitch is set to be substantially the same in the horizontal direction and the vertical direction. When the image shift detection direction is set to the horizontal direction, a set of horizontal pixels 92 in FIG. 38 is used for focus detection. When the image shift detection direction is set to the vertical direction, a set of vertical pixels 92 in FIG. 38 is used for focus detection. When the image shift detection direction is set to 45 degrees, a set of pixels 92 in the 45 degrees direction in FIG. 38 is used for focus detection.
[0120]
When the focus detection position is on the optical axis, as shown in FIGS. 39 and 40, the openings 82 and 83 that are symmetrical with respect to the optical axis of the pupil dividing means 3 and are arranged in the horizontal direction, or the openings that are arranged in the vertical direction. 84 and 85 are alternately switched. In this case, focus detection using the openings 82 and 83 arranged in the horizontal direction and focus detection using the openings 84 and 85 arranged in the vertical direction may be used in combination. Further, when focus detection is performed using either one of focus detection using the openings 82 and 83 or focus detection using the openings 84 and 85 arranged in the vertical direction, and the focus detection becomes impossible, the other is detected. You may make it switch to.
[0121]
When the focus detection position is off the optical axis (when vignetting occurs in the horizontal direction of the drawing), as shown in FIG. 41, it is symmetrical with respect to the center of the overlapping portion 66 due to vignetting and in the horizontal direction of the drawing. The aligned openings 86a and 87a are switched alternately. At this time, the image shift detection direction is set to the horizontal direction, and a set of horizontal pixels 92 shown in FIG. 38 is used for focus detection.
[0122]
Further, when the focus detection position is off the optical axis (when vignetting occurs in the horizontal direction of the drawing), as shown in FIG. 41, it is symmetrical with respect to the center of the overlapping portion 66 due to vignetting and is perpendicular to the drawing. The openings 86b and 87b arranged in the direction may be alternately switched.
[0123]
In this case, the image shift detection direction is set to the vertical direction, and the set of pixels 92 in the vertical direction in FIG. 38 is used for focus detection.
Further, when the focus detection position is off the optical axis (when vignetting occurs in the vertical direction of the drawing), as shown in FIG. 42, it is symmetric with respect to the center of the overlapping portion 66 due to vignetting and is horizontal in the drawing. The openings 88 and 89 arranged in a row are alternately switched. At this time, the image shift detection direction is set to the horizontal direction, and in FIG. 38, a set of pixels 92 in the horizontal direction is used for focus detection.
[0124]
Further, when the focus detection position is off the optical axis (when vignetting occurs in the 45 ° direction rising to the right in the drawing), as shown in FIG. 43, it is symmetric with respect to the center of the overlapping portion 66 due to vignetting, In the drawing, openings 90 and 91 arranged in the 45 ° upward direction are alternately switched. At this time, the image shift detection direction is set to the 45 ° upward direction, and a set of pixels 92 in the 45 ° upward direction in FIG. 38 is used for focus detection.
[0125]
The advantage of the pupil dividing means 3 shown in FIG. 37 is that image deviation detection in four directions is possible by configuring the pupil dividing means 3 from a plurality of square openings.
In addition, the aperture alignment direction and the pixel set direction are set so that image shift detection is performed in a direction perpendicular to the direction in which vignetting occurs (the direction connecting the point on the optical axis and the focus detection position). By doing so, the identity of the pair of focus detection light beams is ensured, and it is possible to prevent a decrease in focus detection accuracy due to the asymmetry of the aberration of the photographing optical system.
[0126]
FIG. 44 is a diagram showing a fourth specific example of the pupil dividing means 3 for preventing the light quantity imbalance between a pair of light fluxes caused by vignetting. As shown in FIG. 44, the pupil dividing means 3 also serves as the photographing aperture 62. The pupil dividing means 3 is composed of a plurality of fan-shaped openings 93 divided by a radial boundary line passing through the optical axis. Each fan-shaped opening 93 can independently control light shielding and light transmission. In this embodiment, the boundary line is formed by radiation in the horizontal direction, the vertical direction, 45 degrees to the right, and 45 degrees to the left. In FIG. 44, the image shift detection directions for focus detection are set in four directions: a horizontal direction, a vertical direction, a right 45 degree direction, and a left 45 degree direction. Further, the pupil dividing means 3 shown in FIG. 44 is used in combination with the photoelectric conversion means 4 shown in FIG.
[0127]
As shown in FIG. 45, when the focus detection position is on the optical axis, the two openings 94 and 95 divided by the vertical boundary line are alternately switched.
As shown in FIG. 46, when the focus detection position is off the optical axis (when vignetting occurs in the vertical direction of the drawing), the vertical direction is symmetric with respect to the center of the overlapping portion 66 due to vignetting. The two openings 94 and 95 divided by the boundary line are alternately switched. At this time, the image shift detection direction is set to the horizontal direction, and the set of horizontal pixels 92 is used for focus detection in the photoelectric conversion means 4 shown in FIG.
[0128]
As shown in FIG. 47, when the focus detection position is off the optical axis (when vignetting occurs in the horizontal direction of the drawing), the horizontal position is symmetric with respect to the center of the overlapping portion 66 due to vignetting. The two openings 96 and 97 divided by the direction boundary line are alternately switched. At this time, the image shift detection direction is set to the vertical direction, and in the photoelectric conversion means 4 shown in FIG. 38, a set of pixels 92 in the vertical direction is used for focus detection.
[0129]
Further, as shown in FIG. 48, when the focus detection position is off the optical axis (when vignetting occurs in the direction of 45 degrees upward to the right in the drawing), it becomes symmetric with respect to the center of the overlapping portion 66 due to vignetting. In this way, the two openings 98 and 99 divided by the boundary line in the 45 ° upward direction are alternately switched. At this time, the image shift detection direction is set to the 45 ° upward direction, and the set of pixels 92 in the 45 ° upward direction is used for focus detection in the photoelectric conversion means 4 shown in FIG.
[0130]
The advantage of the pupil dividing means 3 shown in FIG. 44 is that image deviation detection in four directions is possible by configuring the pupil dividing means 3 from a plurality of fan-shaped openings.
In addition, the alignment direction of the pupil division openings and the direction of the pixel set are set so that image shift detection is performed in a direction perpendicular to the direction in which vignetting occurs (the direction connecting the point on the optical axis and the focus detection position). By setting, the identity of the pair of focus detection light beams is ensured, and it is possible to prevent a decrease in focus detection accuracy due to the asymmetry of the aberration of the photographing optical system.
[0131]
In addition, since the number of openings can be reduced as compared with the embodiment shown in FIG. 37, the device configuration can be simplified and the operation control can be simplified.
Further, even when vignetting occurs, the vignetting can be divided into almost two and used as a light beam for focus detection, so that the low brightness limit of focus detection can be maintained even at a focus detection position outside the optical axis.
[0132]
FIG. 49 is a diagram showing a fifth specific example of the pupil dividing means 3 for preventing the light quantity imbalance between a pair of light fluxes caused by vignetting. As shown in FIG. 49, the pupil dividing means 3 also serves as the photographing aperture 62. The pupil dividing means 3 is composed of a plurality of strip-shaped openings 100 divided by the boundary line 101 in the vertical direction, and each strip-shaped opening 100 can control light shielding and light transmission independently. The image shift detection direction for focus detection is set in the horizontal direction in FIG.
[0133]
As shown in FIG. 50, when the focus detection position is on the optical axis, the two openings 102 and 103 divided on the left and right are alternately switched by a vertical boundary line 101 passing through the optical axis.
As shown in FIG. 51, when the focus detection position is off the optical axis (when vignetting occurs in the horizontal direction in the drawing), the horizontal position is symmetrical with respect to the center of the overlapping portion 66 due to vignetting. The two openings 105 and 106 divided on the left and right at the boundary line 104 in the vertical direction are switched alternately.
[0134]
As shown in FIG. 52, when the focus detection position is further off the optical axis near the screen periphery (when vignetting occurs in the horizontal direction of the drawing), vignetting further proceeds. In this case, the two openings 108 and 109 divided on the left and right at the boundary line 107 in the vertical direction are alternately switched so as to be substantially symmetrical in the horizontal direction with respect to the center of the overlapping portion 66 due to vignetting.
[0135]
The advantage of the pupil dividing means 3 shown in FIG. 49 is that the vignetting can be divided into approximately equal parts by adjusting the position of the boundary between the two openings according to the degree of vignetting. The balance can be prevented.
FIG. 53 is a diagram showing a sixth specific example of the pupil dividing means 3 for preventing light quantity imbalance between a pair of light fluxes caused by vignetting. As shown in FIG. 53, the pupil dividing means 3 also serves as the photographing aperture 62. The pupil dividing means 3 includes openings 110, 111, and 112 that form two elliptical openings that overlap each other in the horizontal direction. Each of the openings 110, 111, and 112 can independently control light shielding and light transmission. The image shift detection direction for focus detection is set in the horizontal direction in FIG.
[0136]
When performing the focus detection position, as shown in FIGS. 54 and 55, the elliptical opening composed of the openings 110 and 112 and the elliptical opening composed of the openings 111 and 112 are alternately switched.
The advantage of the pupil dividing means 3 shown in FIG. 49 is that the amount of light necessary for focus detection can be ensured by switching the openings overlapping each other in this way.
[0137]
Further, by superimposing the openings, when focus detection is performed at a position outside the optical axis, it is possible to reduce the unbalance of the light amounts of the pair of focus detection light beams due to the influence of vignetting.
FIG. 56 is a diagram showing a specific example when the pupil dividing means 3 is configured by DMD (DEGITAL MIRROR DEVICE). The DMD is formed as a set of fine mirror structures 120 as shown in FIG.
[0138]
FIG. 57 is a view showing the fine mirror structure 120. As illustrated, in the mirror structure 120, a mirror 123 is formed on a shaft 122 formed on a substrate 121 by a semiconductor process. The mirror 123 changes its angle with respect to the axis 122 by applying an electrical control signal.
58 and 59 are diagrams showing an example of the operation of the pupil dividing means 3 formed by DMD. As shown in FIG. 58, the pupil dividing means 3 formed of DMD is divided into two parts 124 and 125, and these two parts 124 and 125 constitute a pair of openings.
[0139]
The pupil dividing means 3 is disposed in the photographing optical path and has a function of deflecting a focus detection light beam. As shown in FIG. 59, when the mirror 123 is controlled in parallel with the substrate 121, the reflected light beam is deflected in the direction of the photoelectric conversion means 4. When the mirror 123 is controlled to be non-parallel to the substrate 121, the reflected light beam is deflected in a direction other than the photoelectric conversion means 4. Therefore, by alternately controlling the mirrors 123 of the two portions 124 and 125, the light beam reflected by the portion 124 and the light beam reflected by the portion 125 are alternately received by the photoelectric conversion means 4.
[0140]
The advantage of configuring the pupil division means 3 with a DMD is that the aperture can be switched at an extremely high speed because the operating characteristics of the DMD are faster than those of the liquid crystal.
In the above description, as shown in FIG. 58, the DMD is divided into two parts 124 and 125. Needless to say, there are various division methods.
[0141]
(Other configuration of photoelectric conversion means 4)
FIG. 60 is a partially enlarged view showing another example in which the photoelectric conversion means 4 is constituted by a two-dimensional CCD sensor.
In the two-dimensional CCD sensor shown in FIG. 10, gates 52, 53, 56, charge storage units 54, 55, and CCD charge transfer unit 57 are arranged only on one side with respect to the column of photoelectric conversion pixels 51.
However, in the two-dimensional CCD sensor shown in FIG. A CCD charge transfer unit 159 is disposed. The arrangement of the photoelectric conversion pixels 151 of the photoelectric conversion means 4 is the same as that of the two-dimensional CCD sensor shown in FIG.
[0142]
According to the two-dimensional CCD sensor shown in FIG. 60, gates 152 and 153 and charge storage units 154 and 155 arranged on both sides of the pixel are provided for one pixel. Therefore, when the aperture is switched, the charges corresponding to the images formed by the different apertures can be stored in the separate charge storage portions 154 and 155 by switching the gates 152 and 153.
[0143]
The operation of the photoelectric conversion means 4 shown in FIG. 60 is as follows. The photoelectric conversion pixel 151 generates a charge corresponding to the amount of incident light. Before the charge accumulation, the gates 152 and 153 are closed, and the generated charges are thrown away to a drain (not shown). The gates 152 and 153 open and close alternately during charge accumulation. Thus, charges generated in the photoelectric conversion pixel 151 while the gate 152 is open are accumulated in the charge accumulation unit 154. In addition, charges generated in the photoelectric conversion pixel 151 while the gate 153 is open are stored in the charge storage unit 155. During this time, the gates 156 and 158 are closed.
[0144]
When charge accumulation is completed, the gates 152 and 153 are closed, and then the gates 156 and 158 are opened. As a result, the charges accumulated in the charge accumulation unit 154 and the charge accumulation unit 155 move to the CCD charge transfer units 157 and 159, and are then transferred according to the operation clock of the CCD and output to the outside as electric signals.
The photoelectric conversion means 4 shown in FIG. 60 has the advantage that by providing charge storage portions on both sides of the pixel, the size of the charge storage portion can be increased as compared with the structure of the two-dimensional CCD sensor shown in FIG. The amount of charge can be increased, and the dynamic range of the output signal can be expanded.
[0145]
Even in the case of the same pixel size, since the size of the gate and the charge storage portion is larger than that of the structure shown in FIG. 10, the semiconductor process is easy and the manufacturing yield is good.
Further, by sharing the CCD charge transfer units 57 and 59 with the photoelectric conversion pixel columns (not shown) (photoelectric conversion pixel columns on the upper and lower sides in FIG. 60), the aperture efficiency of the pixels can be improved.
[0146]
FIG. 61 is a schematic diagram showing a specific example in which the photoelectric conversion means 4 is configured using two two-dimensional CCD sensors. In general, a two-dimensional CCD sensor has a small pixel sensitivity gap in a pixel row in a direction along the CCD charge transfer unit. Further, the two-dimensional CCD sensor has a large gap in the pixel column in the direction perpendicular to the direction along the CCD charge transfer unit because the charge storage unit, the gate, and the CCD transfer unit exist. Therefore, since the focus detection accuracy is improved by using the pixel row in the direction along the CCD charge transfer unit, it is desirable to detect the image shift in this direction.
[0147]
Therefore, it is possible to divide the opening of the pupil dividing means 3 into two directions such as the horizontal direction and the vertical direction (see the pupil dividing means 3 etc. shown in FIG. 37). When performing image shift detection in a direction, a focus detection device capable of detecting image shift in two directions with high accuracy can be provided by providing a two-dimensional CCD sensor in which pixel rows are aligned in each direction.
[0148]
The configuration shown in FIG. 61 shows, for example, a portion that is replaced with the photoelectric conversion means 4 in the embodiment shown in FIG. That is, the half mirror 128 shown in FIG. 61 is arranged in the optical path that has passed through the main mirror 13 shown in FIG. 20, and the light beam is divided into two. Two photoelectric conversion means 126 and 127 are arranged on the image plane in the divided optical path.
[0149]
In FIG. 61, the pixel column direction of the photoelectric conversion means 126 is the direction of the arrow X (the horizontal direction in the drawing), and is used when the image shift detection direction is the direction of the arrow X. Similarly, it is the direction of the pixel column of the photoelectric conversion means 127 in the direction Z (the direction perpendicular to the paper surface), and is used when the image shift detection direction is the Z direction.
FIG. 62 is a plan view of the photoelectric conversion means 126, 127 shown in FIG. 62, on the photoelectric conversion means 126 and 127, the pixel row 129 has a structure in which the pixel gap is small in the direction of the arrow.
[0150]
63 and 64 are explanatory diagrams showing an AGC (AUTOMATIC GAIN CONTROL) method when a two-dimensional CCD sensor is used as the photoelectric conversion means 4.
Usually, in the case of a two-dimensional sensor, all pixels are set to the same charge accumulation time. As a result, the output signal level is optimized only for a part of the screen, and some part of the screen is too bright and overflows to exceed the dynamic range, and the other part is too dark and the amount of output signal is insufficient. To do. Therefore, when such a two-dimensional sensor is applied to the present invention, accurate focus detection can be performed only on a part of the screen.
[0151]
Therefore, as shown in FIG. 63, all the pixels arranged two-dimensionally in the photoelectric conversion means 4 are divided into a plurality of blocks 130 (9 blocks in the figure), and each block 130 is independently set. AGC is executed. FIG. 64 shows a plurality of photoelectric conversion pixels 151 included in one block 130.
By applying the above-described AGC method to the present invention, the output signal level becomes an appropriate level within the dynamic range in any part of the screen according to the luminance of each block 130 on the screen.
[0152]
FIG. 65 is a time chart showing operation timings of aperture switching in the pupil dividing unit 3 and charge accumulation in the photoelectric conversion unit 4.
In the time chart shown in FIG. 11, the opening of the pupil dividing means 3 and the gate of the photoelectric conversion means 4 are controlled by the signal waveforms shown in FIGS. Actually, the operation of the opening has a transition period between ON and OFF, like the signal waveforms shown in FIGS. 65 (a) and 65 (b). Therefore, when both the opening / closing operation of the pupil dividing unit 3 and the gate opening / closing operation of the photoelectric conversion unit 4 are controlled by the signal waveforms shown in FIGS. 11A and 11B, the charge obtained by the photoelectric conversion unit 4 is obtained. Contains a lot of crosstalk components, which adversely affects the detection accuracy of image shift.
[0153]
Therefore, as in the signal waveforms shown in FIGS. 65C and 65D, the gates 52, 53, and 152 of the photoelectric conversion means 4 are turned on and off only during the period when the aperture is substantially turned on or off. , 153 can be controlled to reduce the crosstalk component.
[0154]
(Correction of focus detection result)
66 and 67 are diagrams for explaining a method of correcting the focus detection result when the aperture switching operation of the pupil dividing unit 3 and the driving for focus adjustment of the photographing optical system are overlapped.
FIG. 66 is a time chart showing the accumulation of charges in the photoelectric conversion means 4, the transfer of the accumulated charges from the photoelectric conversion means 4 to the calculation control means 5, and the calculation time in the calculation control means 5. That is, FIG. 66 (a) shows a signal waveform when charge accumulation is performed with one opening opened, and the central time of charge accumulation is T1. FIG. 66B shows a signal waveform when charge accumulation is performed with the other opening opened, and the central time of charge accumulation is T2. FIG. 66 (c) shows the time required to transfer the accumulated charge from the photoelectric conversion means 4 to the arithmetic control means 5. FIG. 66 (d) shows the time required to perform image shift detection calculation based on the signal fetched by the calculation control means 5, and finally calculate the drive amount of the photographing optical system for focus adjustment. The calculation ends at time T3.
[0155]
FIG. 67 is a diagram showing the relationship between the lens position of the photographic optical system and the drive time. That is, the photographic optical system is driven to the in-focus position based on the previous instruction from the arithmetic control means 5, and is located at position P1, time T2, position P2 at time T2, and position P3 at time T3. Therefore, the photographing optical system is moved between a central time T1 when the charge is accumulated by opening one opening and a central time T2 when the charge is accumulated by opening the other opening. If the photographic optical system moves, an image shift occurs correspondingly, so that it is necessary to correct the focus detection result by the image shift amount. Further, since the photographing optical system is driven between the central times T1 and T2 when charge accumulation is performed and the time T3 when the calculation is completed, it is necessary to correct the amount accordingly.
[0156]
The above-described drive amount correction is performed as follows. The position P1 of the photographing optical system at the central time T1 at which charge is accumulated by opening one of the openings is detected. Next, the position P2 of the photographing optical system at time T2 when the other opening is opened and charge is accumulated is detected. Then, an average position P4 of the positions P1 and P2 represented by the following equation (9) is set as a representative position at the time of charge accumulation.
[0157]
P4 = (P1 + P2) / 2 (9)
Assuming that the drive amount calculated by the calculation control means 5 at time T3 is S, the corrected drive amount ΔS is calculated by the equation (10) in order to correct the movement amount from the charge accumulation time to the end of the calculation.
ΔS = S- (P3-P4) (10)
Accurate focus detection can be performed by obtaining the correction drive amount ΔS in the arithmetic control means 5.
[0158]
【The invention's effect】
As is clear from the above description, according to the present invention, since there is no decrease in the amount of light due to the presence of the polarizing plate or the presence of the dye molecules, high-speed operation for focus detection becomes possible.
Further, since the pupil dividing means can maintain a high light transmittance even when the power is turned off, bright observation by the finder can be performed.
Further, since no polarizing plate is used, an alignment step is not required, the assembly is simplified, and the cost can be reduced.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing two apertures and photoelectric conversion means provided at an exit pupil position of an imaging optical system.
FIGS. 2A and 2B are explanatory views showing a state in which an imaging optical system is in focus.
FIGS. 3A and 3B are explanatory views showing a front pin state in which the focal position of the imaging optical system is present at a position before the in-focus position.
FIGS. 4A and 4B are explanatory diagrams showing a rear pin state in which the focal position of the imaging optical system is present behind the in-focus position.
FIG. 5 is an explanatory diagram showing an outline of the configuration of an embodiment when the focus detection apparatus of the present invention is applied to a single-lens reflex camera.
FIG. 6 is a diagram showing a specific example in which pupil dividing means is configured using a liquid crystal shutter.
FIGS. 7A and 7B are explanatory views showing the operation of the pupil dividing means.
FIGS. 8A and 8B are diagrams showing examples of liquid crystal used for a liquid crystal shutter constituting the pupil dividing unit. FIGS.
FIG. 9 is an explanatory view showing an example in which the photoelectric conversion means is constituted by a two-dimensional CCD sensor.
10 is a partially enlarged view of the two-dimensional CCD sensor shown in FIG.
FIG. 11 is a diagram illustrating operation timings of opening switching and charge accumulation.
12 is an explanatory diagram showing an outline of a configuration of a variation of the embodiment shown in FIG.
13 is an explanatory diagram showing an outline of a configuration of a variation of the embodiment shown in FIG.
14 is an explanatory diagram showing an outline of the configuration of another variation of the embodiment shown in FIG. 12. FIG.
FIG. 15 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. 12;
16 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 15;
FIG. 17 is an explanatory diagram showing a schematic configuration of an embodiment when a focus detection apparatus according to the present invention is applied to an electronic finder type silver salt camera.
18 is an explanatory diagram showing a schematic configuration when the embodiment shown in FIG. 17 is applied to an electronic camera.
FIG. 19 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 18;
20 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 19;
FIG. 21 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. 19;
22 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 21. FIG.
23 is an explanatory diagram showing a schematic configuration of another variation of the embodiment shown in FIG. 21. FIG.
24 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 23. FIG.
FIG. 25 is an explanatory diagram showing a schematic configuration when the embodiment shown in FIG. 19 is applied to a lens-integrated electronic camera.
26 is an explanatory diagram showing a schematic configuration of a variation of the embodiment shown in FIG. 22;
FIG. 27 is an explanatory diagram showing an example in which vignetting occurs due to the lens outer diameter of the photographing optical system.
FIG. 28 is an explanatory diagram showing vignetting caused by vignetting due to the lens outer diameter of the photographing optical system.
FIG. 29 is a diagram showing a first specific example of pupil dividing means for preventing the influence of vignetting.
30 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 29. FIG.
31 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 29. FIG.
32 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 29. FIG.
FIG. 33 is a diagram showing a second specific example of pupil dividing means for preventing the influence of vignetting.
34 is an explanatory diagram showing the operation of the pupil dividing means shown in FIG. 33. FIG.
35 is an explanatory diagram showing the operation of the pupil dividing means shown in FIG. 33. FIG.
36 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 33. FIG.
FIG. 37 is a diagram showing a third specific example of pupil dividing means for preventing the influence of vignetting.
38 is a diagram showing a configuration of photoelectric conversion means used in combination with the pupil dividing means shown in FIG.
39 is an explanatory diagram showing the operation of the pupil dividing means shown in FIG. 37. FIG.
40 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 37. FIG.
41 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 37. FIG.
42 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 37. FIG.
43 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 37. FIG.
44 is a diagram showing a fourth specific example of pupil dividing means for preventing the influence of vignetting. FIG.
45 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 44. FIG.
46 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 44. FIG.
47 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 44. FIG.
48 is an explanatory diagram showing the operation of the pupil dividing means shown in FIG. 44. FIG.
FIG. 49 is a diagram showing a fifth specific example of pupil dividing means for preventing the effects of vignetting.
50 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 49. FIG.
51 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 49. FIG.
52 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 49. FIG.
FIG. 53 is a diagram showing a sixth specific example of pupil dividing means for preventing the effects of vignetting.
54 is an explanatory diagram showing the operation of the pupil dividing means shown in FIG. 53. FIG.
55 is an explanatory view showing the operation of the pupil dividing means shown in FIG. 53. FIG.
FIG. 56 is a diagram showing a specific example in the case where the pupil dividing means is configured by DMD (DEGITAL MIRROR DEVICE).
57 shows a fine mirror structure in the DMD shown in FIG. 56. FIG.
FIG. 58 is a diagram showing an example of the operation of pupil division means formed by DMD.
FIG. 59 is a diagram showing an example of the operation of pupil dividing means formed by DMD.
60 is a partially enlarged view showing another example in which the photoelectric conversion means is configured by a two-dimensional CCD sensor. FIG.
FIG. 61 is a schematic diagram showing a specific example in which the photoelectric conversion means is configured using two two-dimensional CCD sensors.
62 is a plan view of the photoelectric conversion means shown in FIG. 61. FIG.
FIG. 63 is an explanatory diagram showing an AGC (AUTOMATIC GAIN CONTROL) method when a two-dimensional CCD sensor is used as the photoelectric conversion means.
FIG. 64 is an explanatory diagram showing an AGC (AUTOMATIC GAIN CONTROL) method when a two-dimensional CCD sensor is used as the photoelectric conversion means;
FIG. 65 is a time chart showing operation timings of aperture switching in the pupil division unit and charge accumulation in the photoelectric conversion unit;
FIG. 66 is a time chart showing charge accumulation in the photoelectric conversion means, transfer of the accumulated charges from the photoelectric conversion means to the calculation control means, and calculation time in the calculation control means.
FIG. 67 is a diagram illustrating a relationship between a lens position of the photographing optical system and a driving time.
68 (a) and 68 (b) are explanatory views showing examples of liquid crystal used for a liquid crystal shutter constituting the pupil dividing means.
69 (a) and 69 (b) are diagrams showing other examples of liquid crystal used for a liquid crystal shutter constituting the pupil dividing means.
[Explanation of symbols]
1 Camera body
2 Interchangeable lens structure
3 pupil division means
4 photoelectric conversion means
5 Calculation control means
10 Penta prism
11 Shutter
12 films
13 Main mirror
14 Submirror
15 Imaging means
16 Memory means
17 Reduction optical system
18 Display means
19 Observation optical system
20 Shooting optical system
21 Information means
22 condenser lens
23 Re-imaging lens
25 Dach
26,128 half mirror
27 Photometric means
30 300 Liquid crystal molecules
31 310 Glass substrate
32 320 Transparent electrode
35 350 Power supply
36 360 switch
38 Liquid crystal grains
44, 45, 67, 68, 70, 72, 74, 75, 77, 79, 81, 82, 84, 86, 88, 90, 93, 94, 96, 98, 100, 102, 103, 105, 106, 108,109 opening
51,151 photoelectric conversion pixel
52, 53, 56, 152, 153, 156, 158 gate
54, 55, 154, 155 Charge storage unit
57,157,159 Charge transfer unit
60 Imaging surface
61 optical axis
62 Imaging aperture
63 Outer diameter of lens
101, 104, 107 border
110, 111, 112 opening
120 mirror structure
130 blocks
121 substrate
122 axis
123 mirror
126,127 photoelectric conversion means
129 pixel array
330,340 Polarizing plate
370 Dichroic dye molecule

Claims (2)

A photoelectric conversion means that is disposed on an imaging surface of a photographing optical system that forms an image of a light beam from a subject and converts the image of the subject into an image signal;
An observation optical system capable of observing the image of the subject by the photographing optical system;
A plurality of apertures arranged in an optical path between the imaging optical system and the photoelectric conversion means and having different gravity positions from each other, and at least one aperture is selected from the plurality of apertures, And pupil dividing means for selecting at least one opening having a center of gravity position different from that of the first opening as a second opening and opening and closing the first and second openings with respect to the luminous flux in a time-sharing manner. When,
With a focus detection device comprising: a focus detection unit that detects an image shift amount based on an image signal of the subject image formed on the photoelectric conversion unit by the pupil division unit and detects a focus state of the photographing optical system In the camera
The pupil dividing unit has a structure in which a reverse polymer dispersed liquid crystal is sandwiched between a pair of plate-like transparent members each having a transparent electrode, and the reflecting unit reflects the light beam to the observation optical system or the focus detection unit. And when the focus is detected at a position outside the optical axis of the imaging optical system on the imaging plane , with respect to the center of the portion where the imaging aperture of the imaging optical system and the outer shape of the lens of the imaging optical system overlap A camera with a focus detection device , wherein the first and second apertures that are symmetrical and arranged in the detection direction of the image shift amount by the focus detection means are selected . The camera with a focus detection device according to claim 1,
The camera with a focus detection device, wherein the reflection means is provided on a front surface or a rear surface of the pupil division means, and reflects the light beam to the observation optical system or the focus detection means, respectively.

Images