JP6160223B2 - Intermediate adapter and measurement system - Google Patents

Description

The present invention relates to an intermediate adapter and a measurement system .

  A measuring device such as a spectral radiance meter that receives a light beam from a measurement object and measures spectral characteristics is known (see Patent Document 1). This measuring apparatus is provided with a collimating optical system for observing the measurement object.

Japanese Patent No. 4454598

  Since the conventional measuring apparatus does not have a function of recording an image, when the light beam from the measurement object is measured, it was impossible to confirm later what the measurement object was with the image.

The intermediate adapter according to the present invention is detachably inserted between the interchangeable lens of the interchangeable lens camera and the camera body, and is provided inside a housing having a predetermined width in the optical axis direction of the interchangeable lens. , Splitting the light beam transmitted through the interchangeable lens in two directions, guiding one light beam to the imaging means in the camera body, and exchanging with the splitting means for guiding the other light beam to the measuring means for optically measuring the light beam In order to form an image of the light flux from the lens toward the camera body on the imaging surface of the imaging means, the light path length of the light flux is compensated for the extension due to the insertion of the housing, and the light flux that has passed through the interchangeable lens is split image showing a compensating optical system for correcting optical aberration caused by transmission means, to the imaging surface or viewfinder screen provided inside the camera body, the measurement range of the measuring means Characterized in that it comprises a projection means for projecting.
A measurement system according to the present invention includes an intermediate adapter according to the present invention, an interchangeable lens, and a camera body.

  According to the present invention, the measurement object can be confirmed after measurement.

It is a figure explaining the structure of the intermediate adapter by one Embodiment of this invention. It is a figure explaining a display screen. It is a figure explaining the optical path which goes to a camera body via an intermediate adapter from an interchangeable lens. It is a spot diagram of the optical system in an intermediate adapter. It is an enlarged view of a beam splitter. It is a figure explaining the structure of the intermediate adapter by a modification.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating a configuration of a measurement system 1 including an intermediate adapter 10 according to the present embodiment. The measurement system 1 includes an intermediate adapter 10, an interchangeable interchangeable lens 20, and a camera body 30. In the measurement system 1, an existing lens interchangeable camera can be used for the interchangeable lens 20 and the camera body 30. The intermediate adapter 10 according to the present embodiment is inserted between the interchangeable lens 20 and the camera body 30, separates a part of the light flux from the interchangeable lens 20 toward the camera body 30, and guides it to the measurement unit 105 to divide the spectrum of the object to be photographed. In addition, the imaging function of an existing interchangeable lens camera can be used as it is, while enabling measurement such as color measurement.

  The intermediate adapter 10 includes a housing 101 that is inserted between the interchangeable lens 20 and the camera body 30. The interchangeable lens 20 is detachably attached to the lens mount 102 provided in the housing 101 of the intermediate adapter 10. Thereby, the intermediate adapter 10 and the interchangeable lens 20 are physically and electrically connected. Further, a housing 101 of the intermediate adapter 10 is detachably attached to a lens mount 301 provided in the camera body 30. Thereby, the intermediate adapter 10 and the camera body 30 are connected physically and electrically. The lens mount 102 of the intermediate adapter 10 and the lens mount 301 of the camera body 30 have the same specifications.

  A beam splitter 103, an adaptive optics system 104, and a measurement unit 105 are provided inside the housing 101 of the intermediate adapter 10. The light beam that has passed through the interchangeable lens 20 and entered the housing 101 of the intermediate adapter 10 enters the beam splitter 103 in a converged state. The beam splitter 103 transmits a part of the light beam incident on the beam splitter 103 and reflects a part of the light beam. The light beam that has passed through the beam splitter 103 passes through the compensation optical system 104 and forms a photographic object image on the image sensor 302 inside the camera body 30.

  Since the housing 101 of the intermediate adapter 10 has a predetermined width in the optical axis direction of the interchangeable lens 20, the optical path length of the light beam that passes through the interchangeable lens 20 and forms an image on the image sensor 302 of the camera body 30 is interchangeable. It extends by the predetermined width as compared with the case where the housing 101 is not inserted between the lens 20 and the camera body 30. For this reason, the compensation optical system 104 compensates for the extension of the predetermined width, so that the light beam that has passed through the interchangeable lens 20 and has passed through the beam splitter 103 is imaged on the image sensor 302.

  Further, since the beam splitter 103 has an effect equivalent to that of a plane parallel plate on the light beam incident on the beam splitter 103, the beam splitter 103 generates optical aberrations such as spherical aberration and chromatic aberration in the light beam incident in a convergent state. . The compensation optical system 104 also has a function of correcting the optical aberration generated by the beam splitter 103 with respect to the light beam transmitted through the beam splitter 103.

  On the other hand, the light beam reflected by the beam splitter 103 is guided to the light capturing port 106 of the measuring unit 105 to form a photographic object image on the light capturing port 106. The light capturing port 106 is disposed on the optical axis of the interchangeable lens 20 and has a function of capturing only the light beam corresponding to a predetermined range at the center of the imaging screen into the measuring unit 105.

  The measuring unit 105 is a device that optically measures the light beam taken in from the light taking-in port 106, and is, for example, a spectral radiance meter or a colorimeter. The spectral radiance meter, the colorimeter, and the like are not described because a known device may be used.

  In addition, a pointer 107 that projects an image having a shape equivalent to that of the light capturing port 106 of the measurement unit 105 is provided inside the housing 101 of the intermediate adapter 10. The light beam emitted from the pointer 107 is reflected by the beam splitter 103, and is transmitted through the interchangeable lens 20 and guided to the same optical path as the light beam transmitted through the beam splitter 103.

  When the camera body 30 has an electronic viewfinder, the light beam emitted from the pointer 107 is guided to the image sensor 302 via the beam splitter 103, and an image having a shape equivalent to the light capturing port 106 is formed on the image pickup surface of the image sensor 302. Project. The camera body 30 displays an image captured by the image sensor 302 on the electronic viewfinder. Therefore, the user can confirm the measurement range of the measurement unit 105 from the projected image of the pointer 107 that overlaps the captured object image in the displayed captured image. On the other hand, when the camera body 30 is a mirror single-lens reflex camera having an optical viewfinder, the light beam emitted from the pointer 107 is reflected by a mirror (not shown) in the camera body 30 via the beam splitter 103 to be a viewfinder screen. Then, an image having a shape equivalent to the light inlet 106 is projected on the finder screen. Therefore, the user can confirm the measurement range by the measurement unit 105 by directly viewing the projection image of the pointer 107 superimposed on the captured object image with the optical viewfinder.

  Further, a control unit 108 that controls each part of the intermediate adapter 10 is provided inside the housing 101 of the intermediate adapter 10. The control unit 108 includes a microcomputer (not shown) and its peripheral circuits. Connected to the control unit 108 are a measurement unit 105, a pointer 107, a memory 109, a pointer light emission button 110, a shutter cable interface 111, and a PC output interface 112.

  Between the interchangeable lens 20 and the camera body 30, exchange of control information such as focus adjustment and exposure control and power supply from the camera body 30 to the interchangeable lens 20 is performed. In the present embodiment, control information such as focus adjustment and exposure control is exchanged between the interchangeable lens 20 and the camera body 30 via the control unit 108 of the intermediate adapter 10. The diaphragm control built in the interchangeable lens 20 is performed by driving a motor in the interchangeable lens 20 by a control signal from the camera body 30.

  The camera body 30 is provided with an accessory shoe 303 to which a flash device such as a speedlight can be attached. One end of a shutter cable 113 for transmitting a signal indicating the shutter open state to the intermediate adapter 10 is inserted into the accessory shoe 303 of the camera body 30. The other end of the shutter cable 113 is inserted into a shutter cable interface 111 provided in the housing 101 of the intermediate adapter 10. A signal indicating the shutter open state output from the camera body 30 is transmitted to the control unit 108 of the intermediate adapter 10 via the accessory shoe 303, the shutter cable 113, and the shutter cable interface 111.

  The pointer light emission button 110 is provided on the upper surface of the housing 101 of the intermediate adapter 10. Only while the pointer light emission button 110 is pressed by the user, the control unit 108 controls the pointer 107 to emit light. The control unit 108 also controls the pointer 107 not to emit light during exposure photometry by the camera body 30, during shooting, and during measurement by the measurement unit 105 performed simultaneously with shooting.

  The control unit 108 controls the measurement operation by the measurement unit 105 and records measurement data indicating the measurement result by the measurement unit 105 in the memory 109.

  One end of a PC interface cable 114 for transmitting measurement data to a personal computer (PC) 40 is inserted into the PC output interface 112 of the intermediate adapter 10. The other end of the PC interface cable 114 is inserted into a PC input interface 401 provided in the PC 40. The measurement data output from the intermediate adapter 10 is transmitted to the PC 40 via the PC output interface 112, the PC interface cable 114, and the PC input interface 401. The intermediate adapter 10 and the PC 40 may not be connected at the time of shooting.

  Here, the flow at the time of performing an optical measurement with the measurement system 1 of the present embodiment will be described. First, the user visually confirms the measurement target (photographing target) using the electronic viewfinder or the optical viewfinder of the camera body 30. At this time, the user presses the pointer light emission button 110 to cause the pointer 107 to emit light and confirm the measurement range by the measurement unit 105.

  The exposure mode of the camera body 30 is given priority to the shutter speed, and the aperture value of the interchangeable lens 20 is fixed at a value brighter than a predetermined F value. This is to prevent the NA (numerical aperture) of the light beam incident on the light intake port 106 from becoming a predetermined value or less.

  When the user determines the shooting composition and presses the shutter button of the camera body 30, the shutter in the camera body 30 is opened and closed, the imaging element 302 performs imaging, and the captured image is stored in the recording medium. At this time, a signal indicating the opened state of the shutter is transmitted from the camera body 30 to the control unit 108 of the intermediate adapter 10 via the accessory shoe 303, the shutter cable 113, and the shutter cable interface 111. The control unit 108 outputs a measurement data acquisition trigger to the measurement unit 105 in synchronization with the timing at which the shutter is opened in accordance with the received signal indicating the open state of the shutter, and takes in the measurement unit 105 from the light intake port 106. The optical measurement of the luminous flux is performed. Thereby, measurement by the measurement unit 105 can be performed simultaneously with photographing by the camera body 30. Then, the control unit 108 acquires measurement data from the measurement unit 105 and stores it in the memory 109.

  The measurement data stored in the memory 109 is transmitted from the intermediate adapter 10 to the PC 40. Image data captured during measurement by the measurement unit 105 is separately transmitted from the camera body 30 to the PC 40. In addition, since a well-known means should just be used about the means to take in the image data preserve | saved at the camera body 30 to PC40, description is abbreviate | omitted.

  Analysis software for analyzing measurement data obtained by the measurement unit 105 is installed in the PC 40 in advance. The PC 40 analyzes the measurement data output from the intermediate adapter 10 using this analysis software. Further, the PC 40 associates the measurement data obtained by the measurement unit 105 with the image data photographed by the camera body 30 at the time of measuring the measurement data, and the photographed image photographed at the time of measurement together with the analysis result of the measurement data is not illustrated. Display on the display device. At this time, as shown in FIG. 2, the PC 40 displays a measurement range image 502 in which the measurement range measured by the measurement unit 105 is indicated by a rectangular frame, superimposed on the captured image 501 captured at the time of measurement. The measurement range image 502 is displayed by drawing a graphic corresponding to the image projected by the pointer 107 by analysis software. Thereby, after measuring the light flux from the measurement object, the user can confirm what the measurement object was in the captured image 501 and which range of the measurement object was measured. Can be confirmed in the measurement range image 502.

-Example-
Next, examples according to the present embodiment will be described. In this embodiment, description will be made assuming that the specifications of the interchangeable lens 20 and the camera body 30 are as follows.
Interchangeable lens flange back length of camera body 30: 40 mm
Size of imaging surface 3021 of camera body 30: Vertical = 17.1 mm × Horizontal = 25.6 mm
Position of exit pupil 201 of interchangeable lens 20: 17 mm from the interchangeable lens flange surface to the object side
Diameter of exit pupil 201 of interchangeable lens 20: Φ = 15 mm
Distance from the exit pupil 201 of the interchangeable lens 20 to the focal plane 202: 50 mm

  FIG. 3 is a diagram illustrating an optical path of a light beam traveling from the interchangeable lens 20 to the camera body 30 via the intermediate adapter 10 in the present embodiment. In this embodiment, the beam splitter 103 has a thickness of the interchangeable lens 20 in the optical axis Ax direction of 5 mm. The beam splitter 103 has a half mirror surface 1031. The half mirror surface 1031 reflects a part of the light beam that has passed through the interchangeable lens 20 and entered the beam splitter 103 to be guided to the measurement unit 105, and partly transmits the light to the imaging surface 3021. The half mirror surface 1031 is configured such that a light beam in a predetermined range (a range including at least an axial light beam) in the vicinity of the optical axis Ax is incident among the light beams that have passed through the interchangeable lens 20 and entered the beam splitter 103. Has been. That is, the half mirror surface 1031 does not divide the entire light beam that has passed through the interchangeable lens 20 and entered the beam splitter 103 in two directions, but divides a portion near the optical axis Ax in two directions. Yes. Therefore, among the light beams incident on the beam splitter 103, the light beams outside the predetermined range are transmitted through the beam splitter 103 without entering the half mirror surface 1031.

  In this embodiment, the adaptive optics system 104 includes, in order from the object side, a convex meniscus lens L1 having a convex shape on the imaging surface 3021 side of the imaging element 302 and a biconcave lens L2. The light beam that has passed through the interchangeable lens 20 and has passed through the half mirror surface 1031 of the beam splitter 103 passes through the convex meniscus lens L1 and the biconcave lens L2 of the compensation optical system 104, and forms an image on the imaging surface 3021 of the imaging element 302. Is done.

  When the interchangeable lens 20 is directly attached to the camera body 30, the focal plane 202 of the interchangeable lens 20 coincides with the imaging surface 3021 of the camera body 30. In this embodiment, by inserting the casing 101 of the intermediate adapter 10 between the interchangeable lens 20 and the camera body 30, the interchangeable lens 20 moves forward 17.5 mm along the optical axis. That is, the optical path length from the interchangeable lens 20 to the imaging surface 3021 of the camera body 30 extends by 17.5 mm. However, the light beam transmitted through the interchangeable lens 20 is imaged on the imaging surface 3021 by moving the focal position backward by 17.5 mm by the compensation optical system 104 by the amount of the extension. In this embodiment, the magnification by the adaptive optics system 104 is 1.673 times.

Table 1 below shows lens data of the optical system from the exit pupil 201 of the interchangeable lens 20 to the imaging surface 3021 of the camera body 30 in the intermediate adapter 10 according to the present embodiment. In Table 1, the surface number indicates the number of each optical surface from the object side, R indicates the radius of curvature of each optical surface, d indicates the distance on the optical axis from each optical surface to the next optical surface (surface Nd represents the refractive index with respect to the d line, and νd represents the Abbe number with respect to the d line.
(Table 1)
Surface number R mm d mm nd νd
0 ∞ -50
1 ∞ 20 Exit pupil Φ = 15mm
2 ∞ 5 1.5 168 63.9
3 ∞ 2
4 -35.2606 2 1.95 29.4
5 -23.5287 2.2
6 -21.8867 1.5 1.6972 53.3
7 397.7278 35.03 Aspheric image surface

Moreover, as shown in Table 1, the lens surface (seventh surface) on the imaging surface 3021 side of the biconcave lens L2 has an aspherical shape. In this embodiment, it is assumed that the aspheric shape is represented by the following expression (1). In equation (1), y is the height from the optical axis, Z is the distance (sag amount) along the optical axis from the tangential plane of the apex of the aspheric surface to the aspheric surface at height y, R is a vertex curvature radius, κ is a conical coefficient, and C _2n is an aspheric coefficient.

Table 2 below shows the aspheric coefficients of the lens surface (seventh surface) on the imaging surface 3021 side of the lens L2.
(Table 2)
κ -43213.98185
C ₄ 7.0145E-06
C ₆ 9.3042E-08
C ₈ -2.0278E-09
C ₁₀ 1.0960E-11

  FIG. 4 shows a spot diagram of the optical system of the intermediate adapter 10 according to the present embodiment. In the spot diagram of FIG. 4, it is assumed that a virtually aberration-free focused light beam is emitted from the interchangeable lens 20, and this light beam is an optical system (beam splitter 103 and compensating optical system 104) of the intermediate adapter 10 according to the present embodiment. The light collection performance after passing through is shown. The evaluation wavelengths are four wavelengths of 435.834 nm (g), 486.133 nm (F), 587.562 nm (d), and 656.273 nm (C). As shown in FIG. 4, the optical system of the intermediate adapter 10 according to the present embodiment has a light collecting performance necessary for imaging object confirmation.

  FIG. 5 is an enlarged view of the beam splitter 103. The beam splitter 103 has a first incident surface 1032 on which the light beam from the interchangeable lens 20 is incident, and a first emission surface 1033 on which the light beam toward the camera body 30 is emitted. The first entrance surface 1032 and the first exit surface 1033 are surfaces perpendicular to the optical axis Ax. The half mirror surface 1031 is provided between the first incident surface 1032 and the first exit surface 1033 and is inclined by 22.5 degrees with respect to the first entrance surface 1032 and the first exit surface 1033. The half mirror surface 1031, the first incident surface 1032, and the first emission surface 1033 are provided on the optical axis Ax. Further, the beam splitter 103 has a second incident surface 1034 on which the light beam from the pointer 107 is incident, and a second emission surface 1035 on which the light beam that passes through the interchangeable lens 20 and is reflected by the half mirror surface 1031 is emitted. .

  A part of the light beam that has passed through the interchangeable lens 20 and entered the beam splitter 103 from the first incident surface 1032 is transmitted through the half mirror surface 1031 and emitted from the first exit surface 1033, and a part is reflected by the half mirror surface 1031. Then, after being totally totally reflected by the first incident surface 1032 and the first emission surface 1033, the light is emitted from the second emission surface 1035 and condensed from the second emission surface 1035 to a position of 11.3 mm. At this position, the light inlet 106 of the measuring unit 105 is installed. The second exit surface 1035 is provided with a diaphragm 1036 having a diameter Φ = 4 mm. Thereby, it is possible to prevent stray light from entering the light intake port 106.

  The light beam emitted from the pointer 107 enters the beam splitter 103 from the second incident surface 1034, is repeatedly totally reflected by the first exit surface 1033 and the first incident surface 1032, and then is reflected by the half mirror surface 1031 to be reflected by the first mirror. The light is emitted from one emission surface 1033 and forms a projected image on the imaging surface 3021.

According to the embodiment described above, the following operational effects can be obtained.
(1) The intermediate adapter 10 is detachably inserted between the interchangeable lens 20 and the camera body 30 of the interchangeable lens camera, and a housing 101 having a predetermined width in the optical axis direction of the interchangeable lens 20; 101, the light beam transmitted through the interchangeable lens 20 is divided into two directions, one light beam is guided to the image sensor 302 in the camera body 30, and the other light beam is optically measured. The optical path length of the light beam is determined by the insertion of the housing 101 so that an image formed by the beam splitter 103 guided to the measurement unit 105 and the light beam traveling from the interchangeable lens 20 to the camera body 30 is formed on the imaging surface 3021 of the image sensor 302. And an compensating optical system 104 that compensates for the stretched portion. With such a configuration, the light beam that has passed through the interchangeable lens 20 can be measured by the measuring unit 105, and the light beam that has passed through the interchangeable lens 20 can be imaged by the camera body 30. Can be confirmed. In addition, with this configuration, while adding an optical measurement function such as a spectral radiance meter and a colorimeter to an existing interchangeable lens camera, various functions provided in the existing interchangeable lens camera (for example, automatic Focus function etc.) can be used as it is. In addition, with this configuration, the intermediate adapter 10 can be simply installed between the interchangeable lens 20 and the camera body 30 of an existing interchangeable lens camera without creating a dedicated camera for optical measurement. it can. Conventionally, a rear converter that is inserted between the interchangeable lens and the camera body is known. However, since the rear converter is mainly used to convert the focal length of the interchangeable lens, the light beam that has passed through the interchangeable lens can be reduced. There is no function to separate and distribute to another optical path. On the other hand, in the intermediate adapter 10 according to the present embodiment, the beam splitter 103 separates a part of the light beam that passes through the interchangeable lens 20 and travels toward the camera body 30 and guides it to the measurement unit 105. In contrast, optical measurement of a subject to be photographed can be performed together with camera photographing.

(2) In the intermediate adapter 10, the half mirror surface 1031 of the beam splitter 103 is disposed so as to split a predetermined range of light beams in the vicinity of the optical axis of the interchangeable lens 20 among the light beams transmitted through the interchangeable lens 20 in two directions. The With such a configuration, the width of the beam splitter 103 in the optical axis Ax direction can be reduced as compared with the case where the entire light beam transmitted through the interchangeable lens 20 is divided. The width can be reduced.

(3) The intermediate adapter 10 includes a pointer 107 that projects an image indicating a measurement range by the measurement unit 105 on an imaging surface 3021 or a finder screen provided in the camera body 30. With such a configuration, the user can confirm the measurement range by the measurement unit 105 when confirming the photographing range by the finder function of the camera body 30.

(4) In the intermediate adapter 10, the control unit 108 receives a signal indicating the open state of the shutter from the camera body 30 via the shutter interface 111, and controls the measurement by the measurement unit 105 according to the signal. With such a configuration, measurement by the measurement unit 105 can be performed simultaneously with photographing by an existing interchangeable lens camera. Further, since the user only has to press the shutter button of the existing interchangeable lens camera, the operation is simple.

(5) In the intermediate adapter 10, the light beam that has passed through the interchangeable lens 20 enters the beam splitter 103 in a converged state. If the light beam transmitted through the interchangeable lens 20 is converted into a parallel light beam and is incident on the beam splitter 103, an optical member for converting the converged light beam into a parallel light beam is required. The width of the housing 101 in the optical axis Ax direction is increased. Therefore, in the present embodiment, the light beam transmitted through the interchangeable lens 20 is incident on the beam splitter 103 in a converged state, and the optical aberration generated in the beam splitter 103 is corrected by the compensation optical system 104, whereby the light of the casing 101 is corrected. The width in the axis Ax direction can be reduced.

(6) In the intermediate adapter 10, the beam splitter 103 includes a half mirror surface 1031 that transmits a part of the light beam that has passed through the interchangeable lens 20 and reflects a part of the beam splitter 103, and a light beam that has passed through the interchangeable lens 20. The incident surface 1032, the second incident surface 1034 on which the light beam from the pointer 107 is incident, the first emission surface 1033 on which the light beam that has passed through the interchangeable lens 20 and transmitted through the half mirror surface 1031 is emitted, and the interchangeable lens 20 And a second exit surface 1035 from which the light beam that has been transmitted and reflected by the half mirror surface 1031 is emitted. The light beam transmitted through the interchangeable lens 20 and reflected by the half mirror surface 1031 is repeatedly totally reflected by the first incident surface 1032 and the first exit surface 1033 and then exits from the second exit surface 1035. With such a configuration, the light beam necessary for measurement can be branched by one member and the branched light beam can be guided to the measuring unit 105. Therefore, the intermediate adapter 10 can reduce the width of the housing 101 in the optical axis Ax direction. Can be thinned. Similarly, since the light beam from the pointer 107 can be guided to the measuring unit 105 with a single member, the intermediate adapter 10 can reduce the width of the housing 101 in the optical axis Ax direction.

-Modification-
In the above-described embodiment, the example in which the adaptive optics system 104 is disposed closer to the image sensor 302 than the beam splitter 103 has been described. However, as shown in FIG. 6, in addition to the compensation optical system 104 (hereinafter referred to as the first compensation optical system 104), the second compensation optical system 120 is provided closer to the interchangeable lens 20 than the beam splitter 103. May be. In this case, the first compensation optical system 104 and the second compensation optical system 120 correct optical aberrations generated by the beam splitter 103 with respect to the light beam that passes through the interchangeable lens 20 and passes through the beam splitter 103, and the housing. The optical path extended by the width of 101 is compensated.

  Further, as shown in FIG. 6, a third compensation optical system 121 may be provided between the beam splitter 103 and the light capturing port 106 of the measurement unit 105. In this case, the first compensation optical system 104 and the third compensation optical system 121 correct the optical aberration generated by the beam splitter 103 with respect to the light beam transmitted through the interchangeable lens 20 and reflected by the beam splitter 103.

  Further, in the above-described embodiment, an example in which the half mirror surface 1031 of the beam splitter 103 is arranged so as to divide a predetermined range of light beams in the vicinity of the optical axis Ax among the light beams transmitted through the interchangeable lens 20 in two directions. However, as shown in FIG. 6, the entire light beam transmitted through the interchangeable lens 20 may be arranged to be divided in two directions.

  Although various embodiments and modifications have been described above, the present invention is not limited to these contents. Other embodiments conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Intermediate adapter, 20 ... Interchangeable lens, 30 ... Camera body, 101 ... Housing, 103 ... Beam splitter, 104 ... Compensation optical system, 105 ... Measuring part, 107 ... Pointer, 108 ... Control part, 302 ... Imaging element

Claims (6)

A housing that is detachably inserted between the interchangeable lens of the interchangeable lens camera and the camera body and has a predetermined width in the optical axis direction of the interchangeable lens;
The light beam that is provided inside the housing and splits the light beam that has passed through the interchangeable lens in two directions, guides one light beam to the imaging means in the camera body, and optically measures the other light beam. Dividing means leading to measuring means to perform,
The interchangeable lens compensates for the extension of the optical path length of the luminous flux due to the insertion of the housing so as to form an image of the luminous flux from the interchangeable lens toward the camera body on the imaging surface of the imaging means. A compensation optical system that corrects optical aberrations caused by the light beam that has passed through the splitting means, and
Projection means for projecting an image showing a measurement range by the measurement means on the imaging surface or finder screen provided in the camera body;
An intermediate adapter comprising: The intermediate adapter according to claim 1,
The intermediate adapter divides a light beam in a predetermined range in the vicinity of the optical axis of the interchangeable lens out of light beams transmitted through the interchangeable lens in two directions. The intermediate adapter according to any one of claims 1 and 2 ,
Receiving means for receiving a signal indicating an open state of the shutter from the camera body;
Control means for controlling measurement by the measuring means in response to the signal received by the receiving means;
An intermediate adapter, further comprising: In the intermediate adapter as described in any one of Claims 1-3 ,
The dividing means transmits a part of the light beam that has passed through the interchangeable lens and reflects a part of the light, an incident surface on which the light beam that has passed through the interchangeable lens is incident, and passes through the interchangeable lens and passes through the interchangeable lens. A first emission surface from which a light beam transmitted through the transmission / reflection surface is emitted, and a second emission surface from which the light beam transmitted through the interchangeable lens and reflected by the transmission / reflection surface is emitted,
The light beam transmitted through the interchangeable lens and reflected by the transmission / reflection surface is repeatedly totally reflected by the entrance surface and the first exit surface, then exits from the second exit surface, and is guided to the measurement means. An intermediate adapter characterized by The intermediate adapter according to claim 1 or 2 ,
The splitting unit includes a transmission / reflection surface that transmits a part of the light beam that has passed through the interchangeable lens and reflects a part thereof, a first incident surface on which the light beam that has passed through the interchangeable lens is incident, and A second incident surface on which a light beam is incident, and an exit surface from which the light beam that has passed through the interchangeable lens and transmitted through the transmission and reflection surface is emitted,
The light beam from the projection means is incident on the dividing means from the second incident surface, is repeatedly totally reflected by the exit surface and the first entrance surface, and then is reflected by the transmission / reflection surface and is reflected from the exit surface. An intermediate adapter which is ejected and guided to the imaging surface or the finder screen.   The intermediate adapter according to any one of claims 1 to 5,
  A measurement system comprising the interchangeable lens and the camera body.

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