JP3404066B2 - Focus detection device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a focus detecting device.

[0002]

2. Description of the Related Art An image formed by a photographing lens is symmetrically divided into two planes including an optical axis by a re-imaging optical system, and re-formed on a photoelectric conversion element array (light receiving element array). Two
A large number of focus detection optical systems that perform focus detection by detecting a positional shift of an image have been proposed so far (for example, JP-A-55-118019 and JP-A-58-1).
06511 and JP-A-60-32012). Each of these devices receives a light amount distribution by a set of re-imaging optical systems at a light receiving element array, and performs focus detection using an output signal thereof.

In the focus detection system, the light receiving elements are usually arranged at equal intervals, and if the distance is 1 pitch, the focusing accuracy is expressed as a relative scale with respect to 1 pitch. Assuming that the focusing accuracy is 1 / M of one pitch (M is a constant) and the defocus amount of the image surface per pitch is α, the focusing accuracy Δ on the image surface is Δ = ± (1 / M) .Alpha .... (1) Here, the larger the value of Δ, the worse the focusing accuracy, and the smaller the value of Δ, the better the focusing accuracy. That is, the larger the value of M, the better the focusing accuracy. M is determined from the degree of coincidence between the images on the two light receiving element arrays to be compared and the calculation accuracy for detecting the degree of correlation (phase shift amount). Further, the larger the number of light receiving elements used to detect the degree of correlation (phase shift amount), the higher the calculation accuracy. For example, in a camera system that requires M of 10 or more, when the phase difference is detected from the correlation of the outputs of 20 elements, the image on the light-receiving element array will show an image on 20 elements ( (20 times the pitch), it is required that the degree of coincidence of images is better than that of 0.1 times the pitch. When converted into one element, the pitch is 0.005 times.

In a conventional focus detection optical system in which a pair of apertures (incident pupils) are arranged at substantially the same distance from the optical axis of the condenser lens, a re-imaging lens of the same shape is attached to the optical axis of the condenser lens. If they are arranged at substantially equal distances, the light flux from the subject near the particularly important optical axis is subjected to the same refracting action. Also, the refracting action changes as the distance from the optical axis increases,
By making the degree of change symmetrical, the focusing degree of the image in the focused state could be easily increased.

[0005]

However, there are cases where the camera system is required to dispose the entrance pupil of the focus detection optical system asymmetrically with respect to the optical axis of the taking lens. Some of the specific examples are shown below.

In FIGS. 9A and 9B, 101 is a finder section, 102 is a photographing lens section, 103 is a focus detection device section, 104 is a screen mat, 105 is a mirror box, 106 is an image pickup surface, and 107 is a main. A mirror, 108 is a field stop, and BM is a sub-mirror. When the entrance pupils of the focus detection optical system are arranged vertically in order to improve the focusing accuracy of the horizontal line object, it is necessary to make the field diaphragm 108 large in the horizontal direction of the paper surface as shown in FIG. 9B. In order to arrange the sub-mirror BM that guides the light flux passing through the field stop 108, it is necessary to make the mirror box 105 large.

On the other hand, FIG. 9A shows a case where the entrance pupils are arranged side by side and the field stop 108 does not need to be large. Increasing the size of the mirror box 105 not only makes the entire camera body larger, but also requires the final surface of the taking lens to be designed away from the image pickup surface 106, resulting in an increase in the size of the taking lens, a complicated configuration, and a deterioration in imaging performance. However, the distance between the final surface of the taking lens and the imaging surface 106 is sufficient for a general body, but it is not possible to mount an imaging lens that does not meet the distance required by the camera as described above. The systematic problem of disappearing occurs. Therefore, in the conventional camera system in which the entrance pupils of the focus detection system are vertically arranged, the NA of the light flux from the photographing lens entering the focus detection optical system is reduced, or the distance measuring field is reduced.
Further, the detectable defocus amount is reduced so that the mirror box 105 does not become large.
However, as shown in FIG. 7, which will be described later, by arranging the entrance pupil of the focus detection optical system asymmetrically with respect to the optical axis of the taking lens, the mirror box 105 is not made large and the NA of the light flux from the taking lens is increased. It is possible to secure a defocus amount that can detect the distance measuring field.

Further, a condenser lens arranged near the planned image forming surface of the image pickup lens, an aperture stop having three or more apertures for ensuring focusing accuracy, a reimage lens and the same number of apertures. Comprised of photoelectric conversion means consisting of a light receiving element array, the photoelectric conversion means receives the light intensity distribution due to the light fluxes respectively passing through different regions of the photographing lens, among the output signals representing the light intensity distribution obtained from the photoelectric means, Focus detection can be performed by detecting the phase difference between two output signals. In a focus detection system having three or more entrance pupils whose centers of gravity are substantially aligned on the same plane, the focus detection system A combination of the entrance pupil asymmetric with respect to the optical axis of the condenser lens will be selected. The effect of providing three openings will be described in detail in the first embodiment described later.
When four apertures are provided, by detecting the phase difference of the output signals representing the light intensity distribution obtained from the two light fluxes passing through the outer area, the focusing accuracy can be improved even though the range defocusing range is narrow. Excellent focus detection is possible. By detecting the phase difference of the output signals representing the light intensity distribution obtained from the two light fluxes passing through the inner area, focus detection is slightly inferior, but focus detection with a wide ranging defocus range can be performed. Further, since the four image displacement directions due to defocus are parallel, and since the portion of the planned image forming surface of the common photographing lens is evaluated, the output by the inner two light fluxes is Or 4 other than the output of the two outer light fluxes
Focus detection can be performed using any two or more outputs from one light receiving element array. As a result, accurate focusing is possible under a wide range of conditions regarding the exit pupil position of the photographing lens and the distance measurement image height.

As described above, in order to obtain these effects,
It is necessary to dispose the entrance pupil of the focus detection optical system asymmetrically with respect to the optical axis of the taking lens, but even in an optical system consisting of a condenser lens and a re-imaging lens having the same power, decentering of two lenses Relationship, when the eccentricity relationship between the aperture and the condenser lens is different, the incidence of the light flux from the subject,
The effect of the re-imaging system on the light flux is different due to changes in the emission conditions, and the degree of image matching deteriorates even in the in-focus state. That is, the detection accuracy of the phase difference deteriorates. Specifically, the size of the image formed on each light-receiving element array formed on the same plane is different. The mismatch of images due to the difference in image distortion (distortion aberration) is corrected in the conventional focus detection optical system as described later.

Next, the function of the optical element of the conventional focus detection optical system and the remaining degree of correction freedom will be described. The main function of the condenser lens of the focus detection optical system is the transmission of the pupil in the so-called relay optical system, the focal length of which is determined from the specifications, and the function of correcting the distortion aberration of the image on each photoelectric conversion element array. . From the above two functions, the shape of the condenser lens is almost determined, and there is not much freedom with respect to the others. The function of the re-imaging lens of the focus detection optical system is where to re-image the image once formed on the planned image forming surface. In the case of a simple optical system, there is not much freedom to the other. In this way, in addition to the functions described above, each optical system element
It is not easy to add a function of matching the images (matching the sizes of the images on the photoelectric conversion element array). Further, if the configuration is made complicated by increasing the number of lens elements, the degree of coincidence between the two images may increase, but the complicated configuration leads to an increase in error factors, and particularly assembly accuracy and adjusting means. It is not preferable from the problem of.

In view of the above-mentioned problems of the prior art, the present invention simply composes the configuration and makes the entrance pupil of the focus detection optical system easy to operate without causing problems such as assembling accuracy and adjusting means. It is an object of the present invention to provide a focus detection system which has a good degree of image matching even if it is arranged asymmetrically with respect to the optical axis.

[0012]

In order to achieve the above object, a focus detecting device according to the present invention is provided with an aperture corresponding to a condenser lens and an entrance pupil arranged in the vicinity of a planned image forming surface of a photographing lens. And a re-imaging lens having a portion, a re-imaging lens, and two or more re-imaging systems for ensuring focusing accuracy, each of which includes a photoelectric conversion unit including a light-receiving element array corresponding to each aperture. Focus detection is performed by detecting the phase difference between the two output signals representing the light intensity distribution obtained from the photoelectric conversion means of the re-imaging system corresponding to the two entrance pupils capable of ensuring the focusing accuracy in the imaging system. In the focus detection optical system that is performed, the centers of gravity are arranged in a substantially straight line on a substantially same plane.
Correspond to three or more entrance pupils
Centers of gravity of three or more openings line up on a substantially straight line
And each of the openings corresponding to the openings.
If the re-imaging lens and each of the light receiving element rows are arranged in a straight line,
So that they do not exist, and each of the light receiving element arrays
In parallel with each other, and
There are a plurality of combinations of re-imaging optical systems that detect the phase difference between the two output signals due to the light flux passing through the common portion.
Of the re-imaging optical system.
Among the combinations, the combination of the re-imaging optical system having an entrance pupil which is arranged at different distances from the optical axis of the condenser lens
Pitch of the light receiving elements of the light receiving element array corresponding to the approximately
To obtain an output signal that looks like it was received with the same magnitude.
The feature is that they are different from each other according to the projected size .

Therefore, the light flux emitted from the subject to be focused is guided to the planned image forming surface by the photographing lens and forms an image on the planned image forming surface if the photographing lens is in focus. The light flux that has passed through the planned image formation plane is incident on each re-imaging system like the light flux that has passed through each entrance pupil. The light flux is guided to the light receiving element array through the condenser lens, the opening, and the re-imaging lens. At this time, the re-imaging optical system having the entrance pupils arranged at different distances from the optical axis of the condenser lens receives different refracting actions to enter the lens element at different positions and different angles, and thus the light receiving element array receives light. Project the subject to different sizes. Since the pitches of the respective light receiving element arrays are different depending on the ratio of the projected size, output signals as if they were received with the same size can be obtained. The lengths of the light receiving elements in the vertical direction may be set at the same ratio.

The apparatus according to the present invention is also used for the preparation of a photographing lens.
Incident with a condenser lens arranged near the constant image plane
Aperture stop with aperture corresponding to pupil and reimaging lens
And photoelectric conversion consisting of light receiving element rows corresponding to the respective openings
Two re-imaging systems that ensure focusing accuracy
With the above, focusing accuracy can be secured in the re-imaging system 2
Obtained from the photoelectric conversion means of the re-imaging system corresponding to one entrance pupil.
To detect the phase difference between two output signals that represent the light intensity distribution
Focus detection optical system
, The center of gravity is almost in line on the same plane 3
3 corresponding to the entrance pupils to have three or more entrance pupils
Make the center of gravity of the above openings almost linear
And reconnecting each of them corresponding to each of the openings.
Do not arrange the image lens and each of the light receiving element rows in a straight line
The light receiving element arrays are
Arranged in a row, common on the planned imaging plane of the taking lens
A plurality of combinations of re-imaging optical systems for detecting the phase difference between the two output signals due to the light flux passing through the
And a set of the re-imaging optical system.
Among them, for combination of re-imaging optical system with entrance pupils arranged at different distances from the optical axis of the condenser lens.
And is approximately the same according to the size projected on each light receiving element row.
Make sure that the output signal is
It is characterized in that the phase difference between the two output signals is detected by applying a correction for compressing or expanding the output signal in the optical element array direction .

Therefore, the light flux emitted from the subject to be focused is guided to the planned image forming surface by the imaging lens, and forms an image on the planned image forming surface if the photographing lens is in focus. The light flux that has passed through the planned image formation plane is incident on each re-imaging system like the light flux that has passed through each entrance pupil. The light flux is guided to the light receiving element array through the condenser lens, the opening, and the re-imaging lens. At this time, the re-imaging optical system having the entrance pupils arranged at different distances from the optical axis of the condenser lens receives different refracting actions because they enter the lens element at different positions and at different angles, so that the light receiving element array is different. Project the subject to the size. Even when the output signals from the respective light receiving element arrays must match, different output signals can be obtained at the ratio of the projected size. The obtained output signal is compressed or expanded in the light receiving element array direction at a ratio of the projected size, and the same phase difference detection as the output signal received with the same size can be performed. Further, the intensity level of the output signal may be set at the same ratio.

Furthermore, the device according to the invention comprises a taking lens
With a condenser lens placed near the planned image plane
Aperture stop with aperture corresponding to pupil and reimaging lens
And a photoelectric converter consisting of a light-receiving element array corresponding to each aperture.
A re-imaging system that ensures focusing accuracy and is composed of a replacement unit is provided.
One or more, and can secure focusing accuracy in the re-imaging system
Obtained from the photoelectric conversion means of the re-imaging system corresponding to the two entrance pupils.
The phase difference between the two output signals that represent the distributed light intensity
Focus detection optics that detect focus by
In the system, the centers of gravity are almost in the same plane
3 corresponding to the entrance pupils to have three or more entrance pupils
The center of gravity of three or more openings will be on a substantially straight line.
And each of the re-arrangements corresponding to the respective openings.
Do not arrange the imaging lens and each of the light receiving element rows in a straight line.
The light receiving element array of each of the above
They are arranged in parallel so that they can be
There are a plurality of combinations of re-imaging optical systems that detect the phase difference between the two output signals due to the light flux passing through the common portion.
And a set of the re-imaging optical system.
Among the alignment, it can be used as a combination of re-imaging optics with an entrance pupil arranged at different distances from the optical axis of the condenser lens.
When focusing, the subject is roughly the same size
It is characterized in that the optical path length between the re-imaging lens of the re-imaging optical system and the light-receiving element array or the principal point interval of the re-imaging lens is different so as to be projected.

Therefore, the light flux emitted from the subject to be focused is guided to the planned image forming surface by the photographing lens and forms an image on the planned image forming surface if the photographing lens is in focus. The light flux that has passed through the planned image formation plane is incident on each re-imaging system like the light flux that has passed through each entrance pupil. The light flux is guided to the light receiving element array through the condenser lens, the opening, and the re-imaging lens. At this time, the re-imaging system having the entrance pupils arranged at different distances from the optical axis of the condenser lens receives different refracting effects because the re-imaging system enters the lens element at different positions and at different angles. Furthermore, the optical path length between the principal point on the rear side of the re-imaging lens and the light-receiving element array differs depending on the refraction effect of each light beam, and the same subject has the same size on the light-receiving element array when focused. Projected. Here, it is preferable to configure each light receiving element array on the same plane in terms of cost, assembling property, and compactness of the entire light receiving element array. Specifically, the distance between the principal points of the re-imaging lens may be different, the thickness of the re-imaging lens may be different, or a parallel plane plate having a different length may be provided between the re-imaging lens and the light receiving element array. Interposing a medium (in this case, the medium does not have to intervene in the re-imaging system having the longest optical path length), or changing the thickness of the cover glass (resin) on the light receiving element array, etc. Can be achieved by

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described below with reference to FIGS. FIG. 1 shows a state in which the apparatus of this embodiment is arranged on the bottom of a single-lens reflex camera body. Moreover, FIG.
FIG. 4 is a perspective view of a focus detection system of this embodiment. This device
A condenser lens 3 arranged near the planned image forming surface 2 of the taking lens 1, a mirror 4 (not shown in FIG. 2) arranged behind the condenser lens 3, and a mirror 4 arranged behind the mirror 4. (In FIG. 1, they are arranged in a direction perpendicular to the paper surface)
Three apertures 5, 6, 7 and three re-imaging lenses 8, 9, 10 corresponding to the respective apertures and re-imaging lenses 8, 9, 1
It is composed of light receiving element arrays 11, 12, and 13 arranged near the image forming positions of the light beams emitted from 0, respectively. In FIG. 1, the light receiving elements are arranged side by side in a direction perpendicular to the paper surface. In this embodiment, a re-imaging system consisting of the planned image-forming surface 2, the opening 5, the re-imaging lens 8 and the light receiving element array 11 is re-imaging system A,
A re-imaging system including a planned image forming surface 2, an opening 6, a re-imaging lens 9 and a light receiving element array 12 is a re-imaging system B, a planned image forming surface 2, an opening 7, a re-imaging lens 10, and light reception. The re-imaging system including the element array 13 is referred to as a re-imaging system C.

FIG. 3 shows a view of the arrangement of the openings 5, 6, 7 and the vertices of the re-imaging lenses 8, 9, 10 viewed from the optical axis direction of the condenser lens. Since the position of the center of gravity of the aperture of each focus detection system is on a straight line, it is possible to deal with each re-imaging system with one light-receiving element array regardless of the combination of re-imaging systems for focus detection. (If the barycentric position of the aperture of each re-imaging system is not on a straight line, a light-receiving element array in which light-receiving elements are arranged in different directions is required for each combination of re-imaging systems for focus detection). Further, the re-imaging lens 10 of the re-imaging system C is decentered in the direction perpendicular to the direction in which the centers of gravity of the openings of the respective re-imaging systems are arranged, or the light receiving element arrays 11, 12, 1 are arranged.
3 were arranged so that they would not line up on a straight line. Due to this effect, the length of the light receiving element arrays 11, 12, 13 can be made sufficiently long.

FIG. 4 shows how the pupil is transmitted between the projection lens and the focus detection optical system. In the figure, 5a, 6a,
7a shows the entrance pupils of the re-imaging systems A, B and C, respectively, and EXM
₁ shows an example of the exit pupil position of the taking lens, coincides with the entrance pupil position of the focus detecting optical system. EXF ₁ shows an example of the exit pupil position of the taking lens, which is closer to the subject than the entrance pupil position of the focus detection optical system. EXR ₁ shows an example of the exit pupil position of the taking lens, which is on the planned image forming surface side from the entrance pupil position of the focus detection optical system. EXM ₁ , E
XF ₁ and EXR ₁ indicate the same Fno size. FIG. 4A shows an object on the optical axis of the taking lens. The light flux passing through the exit pupil at any position of EXM ₁ , EXF ₁ and EXR ₁ is relayed to the re-imaging systems A, B and C.

FIG. 4B shows a subject which forms an image at a position I ₁ away from the optical axis of the taking lens. When the exit pupil position of the taking lens is EXM ₁ , the light flux is relayed to the re-imaging systems A, B and C. When the exit pupil position of the taking lens is EXF ₁ , the light flux is relayed to the re-imaging systems B and C, but not completely re-imaging system A. When the exit pupil position of the taking lens is EXF ₁ , the light beam is relayed to the re-imaging systems A and C, but not completely re-imaging system B. That is, when the exit pupil position of the photographing lens is EXM ₁ , focusing can be performed with high accuracy by performing focus detection from the output signals from the re-imaging systems A and B.
When the exit pupil position of the photographing lens is EXF ₁ , focusing can be reliably performed by performing focus detection from the output signals from the re-imaging systems B and C. When the exit pupil position of the taking lens is EXR ₁ , focusing can be reliably performed by performing focus detection from the output signals from the re-imaging systems A and C. The light flux that has passed through the planned image forming plane is guided to the light receiving element array through the condenser lens, the opening, and the re-imaging lens. At this time, the re-imaging optical system (re-imaging system C for re-imaging systems A and B) having the entrance pupils arranged at different distances from the optical axis of the condenser lens,
Since the light enters the lens element at different positions and at different angles, it receives different refraction effects and projects an object on the light receiving element array in different sizes. Since the pitches of the respective light receiving element arrays are different depending on the ratio of the projected size, output signals as if they were received with the same size can be obtained. The lengths of the light receiving element rows in the vertical direction may be set at the same ratio. In this way, by changing the combination of the re-imaging system depending on the exit pupil position of the photographing lens and the position of the subject to be focused,
As a system, focusing is possible under a wide range of conditions and also highly accurate focusing is possible. Below, an example of the numerical values of this embodiment is shown.

[0022]

[0023]

A circle formed by a radius of curvature RL having a circle shape of y = YL and z = ZL and a radius of curvature RU having y = YU and z = ZU as a center axis.
When the aperture is formed by the overlapping portion of the circles, the aperture shape is shown by the numerical values in the table below.

When the sensor pitch of the re-imaging system A is P, the sensor pitch has the sensor pitch shown in the following table. Further, the sensor pitch may be the same in the re-imaging system A, the re-imaging system B, and the re-imaging system C, and the output value may be processed to obtain the same effect. Further, as shown in FIG. 5, the number of re-imaging systems is increased to four or more, the center of gravity of the entrance pupil of each re-imaging system is arranged on a straight line, and the positional relationship between each entrance pupil and the condenser lens and the reconnection The pitch of the sensor may be changed according to the positional relationship between the optical axes of the image lens and the condenser lens.

Next, a second embodiment will be described. The basic configuration of the device of the second embodiment is the same as that of the device of the first embodiment, but the thickness of the cover resin of the light receiving element array is set to the reimaging system A,
B and re-imaging system C are made different. An example of numerical values according to this embodiment will be shown below.

[0027]

[0028]

A circle formed by a radius of curvature RL having a circular shape of y = YL and z = ZL and a radius of curvature RU having y = YU and z = ZU as the central axes.
When the aperture is formed by the overlapping portion of the circles, the aperture shape is shown by the numerical values in the table below. The number of re-imaging systems is increased to four or more, the center of gravity of the entrance pupil of each re-imaging system is arranged on a straight line, the positional relationship between each entrance pupil and the condenser lens, the optical axis of the re-imaging lens and the condenser lens. The thickness of the cover resin or the cover glass of the sensor may be changed depending on the positional relationship.

FIG. 6 shows a state in which the apparatus of the third embodiment is arranged at the bottom of a single lens reflex camera body. FIG. 7 is a perspective view of the focus detection system of the apparatus of the third embodiment. The present apparatus includes a condenser lens 3 arranged near a planned image forming surface 2 of a taking lens 1 (not shown in FIG. 7), and a mirror 4 (not shown in FIG. 7) arranged behind the condenser lens 3. , Two openings 5 and 6 (arranged in a direction perpendicular to the paper surface in FIG. 6) arranged behind the mirror 4 and two openings 1 arranged asymmetrically with respect to the optical axis of the condenser lens on the paper surface.
4, 15 and four re-imaging lenses 8, 9, 16, 17 corresponding to the respective apertures and re-imaging lenses 8, 9, 16, 17
It is composed of the light receiving element arrays 11, 12, 18, and 19 arranged near the image forming position of the light beam emitted from. In FIG. 6, the light receiving elements are arranged in a direction perpendicular to the paper surface for the light receiving element rows 11 and 12, and a direction perpendicular to the optical axis of the condenser lens on the paper surface for the light receiving element rows 18 and 19. In this embodiment, the planned image forming plane 2, the opening 5,
The re-imaging system including the re-imaging lens 8 and the light-receiving element array 11 is re-imaging A, and the re-imaging system including the planned imaging surface 2, the opening 6, the re-imaging lens 9 and the light-receiving element array 12 is re-formed. Imaging system B, planned imaging plane 2, aperture 14, reimaging lens 16, light-receiving element array 18
The re-imaging system consisting of the re-imaging system C will be referred to as a re-imaging system C, and the re-imaging system consisting of the planned imaging surface 2, the opening 15, the re-imaging lens 17 and the light receiving element array 19 will be referred to as a re-imaging system D. FIG. 6 shows openings 5, 6, 1
The figure which looked at the state which provided 4 and 15 from the optical axis direction of the condenser lens is shown. Here, the re-imaging systems A and B
Has the same operation as the conventional focus detection optical system.

Further, when the finder portion of the camera body is turned up, the light flux which passes through the lower side of the taking lens 1 and enters the re-imaging system C passes through the upper side of the taking lens 1 and re-imaging system D.
The sub-mirror BM can be made small because the light flux incident on the light beam passes through a portion close to the optical axis of the taking lens. FIG. 8 shows the re-imaging systems C and D extracted. In FIG. 8, the light beams incident on the re-imaging system C and the re-imaging system D are respectively subjected to different refracting actions by the condenser lenses, and project the same subject on the light receiving element arrays 18 and 19 with different sizes. Since the pitches of the respective light receiving element arrays are different depending on the ratio of the projected size, output signals as if they were received with the same size can be obtained. It is also possible to set the lengths of the light receiving elements in the vertical direction with the same ratio. The following is an example of numerical values in this embodiment.

Radius of curvature, spacing and refractive index of the lenses of the re-imaging systems A, B, C and D

[0033]

A circle formed by a radius of curvature RL having a circular shape with a diaphragm shape of y = YL and z = ZL and a radius of curvature RU having a circular axis of y = YU and z = ZU.
When the aperture is formed by the overlapping portion of the circles, the aperture shape is shown by the numerical values in the table below.

When the sensor pitch of the sensor pitch re-imaging system C is P, the sensor pitch has the sensor pitch shown by the following numerical values (note that the re-imaging system A,
The sensor pitch of B is the same regardless of P).

Next, a fourth embodiment will be shown. The basic configuration of the device according to this embodiment is the same as that of the third embodiment,
The thickness of the re-imaging lens is different between the re-imaging systems A and B, the re-imaging system C and the re-imaging system D. An example of numerical values according to this embodiment will be shown below.

Radius of curvature, spacing and refractive index of the lenses of the re-imaging systems A, C and D

[0038]

A circle formed by a radius of curvature RL having a circular shape of y = YL and z = ZL and a radius of curvature RU having y = YU and z = ZU as the central axes.
When the aperture is formed by the overlapping portion of the circles, the aperture shape is shown by the numerical values in the table below.

[0040]

As described above, in the apparatus according to the present invention, the entrance pupil of the focus detection optical system is simply asymmetrical with respect to the optical axis of the condenser lens without complicating the structure and causing problems such as assembling accuracy and adjusting means. Even if the focus detection optical system is arranged in the above position, a focus detection optical system with a good degree of image matching can be configured, and the focus detection can be performed with high accuracy, which has various advantages.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a first embodiment according to the present invention.

FIG. 2 is a perspective view of a focus detection system according to the first embodiment of the present invention.

FIG. 3 is a diagram showing the positions of the aperture and the re-imaging lens as seen from the optical axis direction of the condenser lens in the first embodiment of the present invention.

4A and 4B show how pupils are transmitted between the taking lens and the focus detection optical system in the first embodiment of the present invention, FIG. 4A shows a subject on the optical axis of the taking lens, and FIG. 8A is a diagram showing a subject that forms an image at a position away from the optical axis of the taking lens. FIG.

FIG. 5 is a configuration diagram when the number of re-imaging systems in the first embodiment of the present invention is increased to four or more.

FIG. 6 is a configuration diagram of a third embodiment according to the present invention.

FIG. 7 is a perspective view of a focus detection system in a third embodiment of the present invention.

FIG. 8 is a diagram showing states of re-imaging systems C and D in the third embodiment of the present invention.

FIG. 9A shows a case in which the entrance pupils of the focus detection optical system are arranged side by side in order to improve the focusing accuracy of a horizontal line object in the conventional apparatus, in which FIG. FIG. 7B is a diagram showing a case where there is no light, and FIG.

[Explanation of symbols]

1 Photographing lens 2 Planned image forming plane 3 Condenser lens 4 Mirrors 5, 6, 7 Apertures 5a, 6a, 7a Entrance pupils 8, 9, 10 Re-imaging lenses 11, 12, 13 Light receiving element array 14, 15 Opening 16 , 17 re-imaging lens 18, 19 light-receiving element array 101 finder section 102 taking lens section 103 focus detecting section 104 screen mat 105 mirror box 106 imaging surface 107 main mirror 108 field diaphragms A, B, C re-imaging system BM sub-mirror Image forming positions EXM ₁ , EXF ₁ and EXR _{1 of the} photographing lens I ₁ apart from the optical axis of the photographing lens

Continuation of front page (56) Reference JP-A-4-277713 (JP, A) JP-A-59-143112 (JP, A) JP-A-64-56407 (JP, A) JP-A-62-173412 (JP , A) JP 63-163418 (JP, A) JP 1-169420 (JP, A) JP 2-18509 (JP, A) JP 2-58012 (JP, A) JP 2-272410 (JP, A) JP 5-53049 (JP, A) JP 5-66345 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) G02B 7/34

Claims (8)

(57) [Claims] 1. A condenser lens, a brightness stop having an opening corresponding to an entrance pupil, a re-imaging lens, and a light receiving element array corresponding to each opening, which are arranged in the vicinity of an expected image forming surface of a photographing lens. Re-imaging corresponding to two entrance pupils of the re-imaging system, which has two or more re-imaging systems that ensure the focusing accuracy, and which are composed of photoelectric conversion means including In a focus detection optical system in which focus detection is performed by detecting the phase difference between two output signals representing the light intensity distribution obtained from the photoelectric conversion means of the system, the centers of gravity are arranged substantially on the same plane on a substantially straight line. 3 or more
Three or more apertures corresponding to the entrance pupil to have an entrance pupil
The parts are arranged so that the positions of their centers of gravity line up on a substantially straight line, and
The re-imaging lenses and the corresponding re-imaging lenses corresponding to the respective openings.
And each of the light receiving element rows described above should not be arranged in a straight line.
And the respective light receiving element rows are arranged in parallel.
The common part on the planned image plane of the shooting lens.
A plurality of combinations of re-imaging optical systems that detect the phase difference between the two output signals due to the passing light flux can be configured.
As well as to so that, among the combinations of該再imaging optical system, light of the light receiving element array corresponding to the combination of the re-imaging optical system having an entrance pupil which is arranged at different distances from the optical axis of the condenser lens Output signal as if the pitch of the elements was almost the same.
A focus detection device characterized in that they are different from each other according to the projected size so that 2. A condenser lens arranged near the planned image forming surface of the taking lens, an aperture stop having an opening corresponding to the entrance pupil, a re-imaging lens, and a light receiving element array corresponding to each opening. Re-imaging corresponding to two entrance pupils of the re-imaging system, which has two or more re-imaging systems that ensure the focusing accuracy, and which are composed of photoelectric conversion means including In a focus detection optical system in which focus detection is performed by detecting the phase difference between two output signals representing the light intensity distribution obtained from the photoelectric conversion means of the system, the centers of gravity are arranged substantially on the same plane on a substantially straight line. 3 or more
Three or more apertures corresponding to the entrance pupil to have an entrance pupil
The part, arranged so that its center of gravity is substantially a straight line, 且
The re-imaging lenses and the corresponding re-imaging lenses corresponding to the respective openings.
And each of the light receiving element rows described above should not be arranged in a straight line.
And the respective light receiving element rows are arranged in parallel.
The common part on the planned image plane of the shooting lens.
A plurality of combinations of re-imaging optical systems that detect the phase difference between the two output signals due to the passing light flux can be configured.
As well as to so that, among the combinations of該再imaging optical system, in combination of the re-imaging optical system having an entrance pupil which is arranged at different distances from the optical axis of the condenser lens, is projected on the light receiving element array Size
Depending on the size of the output signal
Compress the output signal in the direction of the light receiving element array to obtain
A focus detection device characterized in that a phase difference between two output signals is detected by adding an expansion correction. 3. A condenser lens arranged near the planned image forming surface of the taking lens, an aperture stop having an opening corresponding to the entrance pupil, a re-imaging lens, and a light receiving element array corresponding to each opening. Re-imaging corresponding to two entrance pupils of the re-imaging system, which has two or more re-imaging systems that ensure the focusing accuracy, and which are composed of photoelectric conversion means including In a focus detection optical system in which focus detection is performed by detecting the phase difference between two output signals representing the light intensity distribution obtained from the photoelectric conversion means of the system, the centers of gravity are arranged substantially on the same plane on a substantially straight line. 3 or more
Three or more apertures corresponding to the entrance pupil to have an entrance pupil
The part so that its center of gravity is on a substantially straight line, and
The re-imaging lenses and the corresponding re-imaging lenses corresponding to the respective openings.
And each of the light receiving element rows described above should not be arranged in a straight line.
And the respective light receiving element rows are arranged in parallel.
The common part on the planned image plane of the shooting lens.
A plurality of combinations of re-imaging optical systems that detect the phase difference between the two output signals due to the passing light flux can be configured.
As well as to so that, among the combinations of該再imaging optical system, in combination of the re-imaging optical system having an entrance pupil which is arranged at different distances from the optical axis of the condenser lens, an object when focusing is approximately the same big
The optical path length between the re-imaging lens of the re-imaging optical system and the light-receiving element array or the principal point spacing of the re-imaging lens is different so that the light is projected onto the light-receiving element array. A focus detection device. 4. Arranged in the vicinity of the planned image forming surface of the taking lens.
A condenser lens and an aperture corresponding to the entrance pupil.
It corresponds to the aperture stop, the re-imaging lens and the respective openings.
Focus composed of photoelectric conversion means consisting of a row of light receiving elements
Two entrance pupils that have two or more re-imaging systems that ensure accuracy and that can ensure focusing accuracy among the re-imaging systems
Intensity obtained from the photoelectric conversion means of the re-imaging system corresponding to
By detecting the phase difference between the two output signals representing the distribution
In a focus detection optical system for detecting the focal point , the input is made to have two pairs of entrance pupils arranged in the vertical and horizontal directions.
The pair of apertures corresponding to the pupils are arranged to form the photographing lens.
Of the light flux passing through the common part of the planned image plane of
Of the re-imaging optical system for detecting the phase difference between the two output signals
Allow combinations to be configured vertically and horizontally
Of the combination of the re-imaging optical systems, which are arranged vertically.
Is the entrance pupil spacing of the set whose entrance pupil spacing is arranged laterally.
From the optical axis of the condenser lens so that it is shorter than
Apertures corresponding to entrance pupils arranged at different distances, re-imaging
With a combination of a lens and a re-imaging optical system with a light-receiving element array
Yes, the light receiving element array corresponding to the re-imaging optical system is received.
If the pitch of the optical elements is almost the same,
Depending on the projected size, the mutual
A focus detection device characterized in that they are different . 5. Arranged in the vicinity of the planned image forming surface of the taking lens.
A condenser lens and an aperture corresponding to the entrance pupil.
It corresponds to the aperture stop, the re-imaging lens and the respective openings.
Focus composed of photoelectric conversion means consisting of a row of light receiving elements
Two entrance pupils that have two or more re-imaging systems that ensure accuracy and that can ensure focusing accuracy among the re-imaging systems
Intensity obtained from the photoelectric conversion means of the re-imaging system corresponding to
By detecting the phase difference between the two output signals representing the distribution
In a focus detection optical system for detecting the focal point , the input is made to have two pairs of entrance pupils arranged in the vertical and horizontal directions.
The pair of apertures corresponding to the pupils are arranged to form the photographing lens.
Of the light flux passing through the common part of the planned image plane of
Of the re-imaging optical system for detecting the phase difference between the two output signals
Allow combinations to be configured vertically and horizontally
Of the combination of the re-imaging optical systems, which are arranged vertically.
Is the entrance pupil spacing of the set whose entrance pupil spacing is arranged laterally.
From the optical axis of the condenser lens so that it is shorter than
Apertures corresponding to entrance pupils arranged at different distances, re-imaging
With a combination of a lens and a re-imaging optical system with a light-receiving element array
Yes, it is almost the same according to the size projected on each light receiving element row.
The light is received so that an output signal as if it was received at the same size is obtained.
Add a correction to compress or expand the output signal in the element row direction.
The feature is that the phase difference between the two output signals is detected.
Focus detecting apparatus according to symptoms. 6. Arranged in the vicinity of the planned image forming surface of the taking lens.
A condenser lens and an aperture corresponding to the entrance pupil.
It corresponds to the aperture stop, the re-imaging lens and the respective openings.
Focus composed of photoelectric conversion means consisting of a row of light receiving elements
Two entrance pupils that have two or more re-imaging systems that ensure accuracy and that can ensure focusing accuracy among the re-imaging systems
Intensity obtained from the photoelectric conversion means of the re-imaging system corresponding to
By detecting the phase difference between the two output signals representing the distribution
In a focus detection optical system for detecting the focal point , the input is made to have two pairs of entrance pupils arranged in the vertical and horizontal directions.
The pair of apertures corresponding to the pupils are arranged to form the photographing lens.
Of the light flux passing through the common part of the planned image plane of
Of the re-imaging optical system for detecting the phase difference between the two output signals
Allow combinations to be configured vertically and horizontally
Of the combination of the re-imaging optical systems, which are arranged vertically.
Is the entrance pupil spacing of the set whose entrance pupil spacing is arranged laterally.
From the optical axis of the condenser lens so that it is shorter than
Apertures corresponding to entrance pupils arranged at different distances, re-imaging
With a combination of a lens and a re-imaging optical system with a light-receiving element array
Yes, the subject at the time of focusing is approximately the same size on the light-receiving element array
Re-imaging lens of the re-imaging optics for projection onto
Of the optical path between the light receiving element array and
A focus detection device characterized in that the principal point spacing is different . 7. The light receiving element corresponding to the re-imaging optical system.
Characteristic that the pitch of the light receiving elements in the sub row is the same as each other
The focus detection device according to claim 2 or 5 . 8. The focus detection device according to claim 3, wherein the light receiving element rows are formed on the same plane.