JP5105719B2 - Optical component evaluation apparatus, evaluation method, and optical axis adjustment apparatus using the same - Google Patents

Description

  The present invention relates to an evaluation apparatus and an evaluation method for an optical component, and more particularly to an evaluation apparatus and an evaluation method for a lens unit used when assembling a lens unit such as a camera lens or an imaging unit.

An apparatus for adjusting the optical axis of a lens unit is disclosed in Patent Document 1, for example. The lens unit optical axis adjusting device disclosed here is configured to irradiate the lens unit with a central ray and three or more annular rays parallel to the central ray.
Japanese Patent No. 3208902

  Next, the optical axis adjusting device disclosed in Patent Document 1 will be described with reference to FIGS. 15, 16, and 17. FIG. FIG. 15 is a schematic configuration diagram of the optical axis adjusting device, FIG. 16 is an explanatory diagram regarding image formation of the optical axis adjusting device, and FIG. 17 is a diagram showing an image on the CCD camera receiving surface of the optical axis adjusting device.

  In FIG. 15, the optical axis adjusting device of the lens unit includes a light source 50, a pinhole plate 51, an ND filter 52, a collimator lens 53 and a mirror 54. The pinhole plate 51 is disposed on the left side of the light source 50. The pinhole plate 51 is subjected to pinhole processing of about φ0.6 μm. Further, the ND filter 52 and the collimator lens 53 are arranged on the left side of the pinhole plate 51. The mirror 54 is disposed on the left side of the collimator lens 53.

Further, in FIG. 15, an opaque and flat chart 55 is arranged below the mirror 54. The chart 55 is arranged so that the surface of the chart 55 is perpendicular to the optical axis of the light incident on the chart 55.
In this chart 55, as shown in FIG. 16, the light transmission region is formed at the center point M0 of the chart 55 and 8 points (M1 to M8) arranged at equal intervals on the annular zone around the center point M0. Has been. Pinhole processing is applied to each point of M0 to M8.

  In FIG. 15, the target lens system T is disposed below the chart 55. The target lens system T includes a lens system 56, a ball frame 57, an attachment portion 58 on the main body side, a lens system 59, and an adjustment jig 60. The ball frame 57 holds and fixes the lens system 56. The attachment portion 58 on the main body side has a structure in which the ball frame 57 is inserted. The lens system 59 is a lens system that is disposed on the top of the ball frame 57 and is an adjustment target. The adjustment jig 60 is disposed so as to contact the lens system 59.

  In FIG. 15, there is an image plane 61 at an arbitrary position below the target lens system T. Below the image plane 61, a microscope lens 62, a CCD camera 63, and a focus shaft 64 are arranged. The microscope lens 62 is arranged so that its optical axis coincides with the optical axis of the target lens system T. The CCD camera 63 is disposed below the microscope lens 62. The CCD camera 63 is arranged such that its image receiving surface is perpendicular to the optical axis of the target lens system T.

  The microscope lens 62, the CCD camera 63, and the focus shaft 64 are mounted on an XY table that is moved by a coarse alignment biaxial shaft 65. The image is captured in the image receiving screen of the CCD camera 63 by adjusting the coarse alignment biaxial 65.

Here, imaging of the optical axis adjusting device will be described.
The light emitted from the light source 50 becomes parallel light R through the pinhole plate 51, the ND filter 52 and the collimator lens 53. The parallel light beam R is reflected by the mirror 54 and becomes parallel light R ′ traveling downward from the mirror 54.

  Part of the parallel light R ′ is blocked by the chart 55, and the remaining light passes through the chart 55. Specifically, the parallel light R ′ passes through a pinhole at the center point M0 of the chart 55 and 8 pinholes (M1 to M8) arranged at equal intervals on the annular zone centered on the center point M0. Thus, nine light beams are formed (a pinhole image is formed). Then, the nine light beams that have passed through the chart 55 pass through the target lens system T and enter the image plane 61. At this time, since most of the parallel light R ′ is shielded by the chart 55, only nine pinhole images are formed on the CCD camera 63.

  Here, it is assumed that the optical axis of the lens system 59 is ideally coincident with the optical axes of the lens system 56 and the entire optical system. In this case, in FIG. 16, the light rays R1. By R2, R3, R4, R5, R6, R7, and R8, irradiation points L1 to L8 on the annular zone are obtained. The center position obtained from the barycentric positions of these irradiation points coincides with the barycentric position of the irradiation point L0 obtained by the light ray R0 passing through the lens systems 59 and 56.

  However, when the optical axis of the lens system 59 is deviated from the optical axes of the lens system 56 to the entire optical system, the center position obtained from the center positions of the irradiation points L1 to L8 on the annular zone and the center of gravity of the irradiation point L0. The position will shift. Therefore, in order to match the deviation between the center position obtained from the center of gravity of the irradiation points L1 to L8 on the annular zone and the center of gravity position of the irradiation point L0, in Patent Document 1, the arithmetic processing unit 66 and the fine alignment biaxial The optical axis adjustment using 69 is performed. That is, the arithmetic processing unit 66 calculates the average of the X coordinates XR1 to XRm and the Y coordinates YR1 to YRm for all the pixels of the eight irradiation points constituting the annular zone excluding the irradiation point 67 (see FIG. 17). The center coordinate B (XG, YG) at the center 68 of the annular zone is obtained.

  Next, the deviation (XG-X0, YG-Y0) between the center-of-gravity coordinates A (X0, Y0) at the irradiation point 67 and the center-of-circle coordinates B (XG, YG) of the zonal zone is determined as the on-axis frame amount (ΔX, ΔY) (Evaluation value is obtained). Then, the fine-alignment biaxial shaft 69 is finely moved according to the detected amount of on-axis coma. At that time, the optical system is adjusted by slightly moving the lens system 59 so that the amount of on-axis coma falls within the set standard.

In Patent Document 1, in the detection of the optical axis deviation of the first lens system (lens system 56 in FIG. 15) and the second lens system (lens system 59 in FIG. 15), the variation in the evaluation value is the center of gravity of the central beam, And variations in the center of the annular luminous flux. In other words, the variation in the evaluation value is the variation in the center of gravity coordinates of the central light flux and the central coordinates of the annular light flux. According to the detection method described here, the center coordinates of the annular light flux are calculated from the average value of the eight light fluxes that make up the annular light. That is, the averaging process cancels out the variations in the eight light beams. As a result, the variation in the center coordinates is smaller than the variation in the center of gravity position of each light beam.
However, the center of gravity coordinates of the central light beam are calculated from only one light beam. For this reason, the variation in the center-of-gravity coordinates of one light flux directly affects the evaluation value, which is one of the factors that deteriorate the variation in the evaluation value.

Further, as a recent technical trend, there is a trend of downsizing the lens unit. In order to realize such a miniaturization, the optical axis deviation accuracy required at the time of assembling the lens unit is becoming stricter.
However, when trying to adjust the optical axis of the lens unit using the apparatus described in Patent Document 1, the variation in the evaluation value increases as described above, so that the detection resolution is significantly reduced and the adjustment accuracy is deteriorated. There is a risk that. Therefore, it may be difficult to reduce the size of the lens unit.

Accordingly, the present invention has been made in view of the above problems, and an optical component evaluation apparatus , an evaluation method, and an optical component evaluation device capable of detecting an optical axis shift (or an optical component and frame attachment error) with high resolution. An object of the present invention is to provide an optical axis adjusting device using the above-mentioned.

In order to achieve the above object, an optical component evaluation apparatus according to the present invention includes a light beam generation unit that generates a plurality of light beams, an imaging device that is disposed at a position to receive light from the light beam generation unit, and the imaging A holding member that is disposed closer to the light beam generation unit than the device and holds an optical component; and a processing device that performs predetermined processing based on output information from the imaging device. And a plurality of regions in the first region group are located apart from each other on the first predetermined line, and the plurality of regions in the second region group Are located apart from each other on a second predetermined line, the second region group is located outside the first region group, and the output information includes the output in the first region group. was determined from an image of a plurality of regions, the center position of the first area group And information obtained from the image of the plurality of regions in the second area group, information of the center position of the second area group is included, the processing device, the information of the center position of the first area group And the amount of movement of the optical component necessary for adjusting the position of the optical component based on the information on the center position of the second region group .

  In the optical component evaluation apparatus of the present invention, the light flux generation unit includes a light source and a substrate, and the substrate is disposed between the light source and the holding member or between the holding member and the imaging device. The plurality of regions in the first region group and the second region group are regions that transmit or reflect light.

  In the optical component evaluation apparatus of the present invention, the light flux generation unit is a light source having a plurality of light emitting units, and the plurality of regions in the first region group and the second region group are the plurality of regions. The light emitting sections are arranged at equal intervals on the first predetermined line and the second predetermined line.

  In the optical component evaluation apparatus of the present invention, the first predetermined line is a circumference.

  In the optical component evaluation apparatus of the present invention, the first predetermined line is a polygonal side.

  In the optical component evaluation apparatus of the present invention, the second predetermined line is a circumference.

  In the optical component evaluation apparatus of the present invention, the second predetermined line is a polygonal side.

  In the optical component evaluation apparatus of the present invention, the outer shapes of the plurality of regions in the first region group are all the same.

  In the optical component evaluation apparatus of the present invention, the outer shapes of the plurality of regions in the first region group include at least two different shapes.

  In the optical component evaluation apparatus of the present invention, the outer shapes of the plurality of regions in the second region group are all the same.

  In the optical component evaluation apparatus of the present invention, the outer shapes of the plurality of regions in the second region group include at least two different shapes.

  In the optical component evaluation apparatus of the present invention, the outer shape of the plurality of regions is a circle.

  In the optical component evaluation apparatus of the present invention, the outer shape of the plurality of regions is a polygon.

Further, in the evaluation apparatus of the optical component of the present invention, information of the center position before Symbol first set of regions, and calculates an average value of all the barycentric coordinates of the image of the plurality of regions in said first group of regions The information on the center position of the second region group is information obtained by calculating an average value of all barycentric coordinates of the images of the plurality of regions in the second region group. It is characterized by.

In order to achieve the above object, the optical axis adjustment apparatus according to the present invention is based on the information necessary for the position adjustment of the optical component calculated by the evaluation device for one of the optical components and the processing device, A moving unit that moves in a direction perpendicular to the optical axis of the optical component; and an alignment jig that is arranged to contact the optical component and is connected to the moving unit. And

Furthermore, in order to achieve the above object, an optical component evaluation method according to the present invention includes a first region group including a plurality of regions positioned apart from each other on a first predetermined line, and the first region group. An imaging step of imaging a second region group consisting of a plurality of regions located outside and positioned apart from each other on a second predetermined line via an optical component; and a plurality of regions in the first region group was determined from an image area, and the information of the center position of the first area group, said determined from an image of a plurality of regions in the second area group, based on the information of the center position of the second area group, a calculation step of calculating a movement amount of the optical components required for positional adjustment of the optical component, the you said containing Mukoto.

In the optical component evaluation method of the present invention, the information on the center position of the first region group is obtained by calculating an average value of all barycentric coordinates of images of a plurality of regions in the first region group. The information on the center position of the second region group is information obtained by calculating an average value of all barycentric coordinates of images of a plurality of regions in the second region group. To do.
Further, in the optical component evaluation method of the present invention, the step of adjusting the position of the optical component based on the amount of movement of the optical component required for the position adjustment of the optical component calculated in the calculation step is further performed. It is characterized by including.

Thus, according to the present invention, variation in evaluation values, which was a problem of the prior art, can be suppressed. As a result, it is possible to provide an optical component evaluation apparatus, an evaluation method, and an optical axis adjustment apparatus using the same, which can evaluate optical axis misalignment (or optical component and frame attachment error) with high resolution. As a result, it is possible to adjust a small lens unit that has a severe tolerance for optical axis deviation. Therefore, it can contribute to size reduction of a lens unit.

The evaluation of the optical component in the embodiment is, for example, evaluating an optical axis shift between optical components and an attachment error between the optical component and the frame. More specifically, in making an adjustment to make the optical axis deviation and the mounting error zero or sufficiently small, information that can be adjusted is obtained. In this evaluation, the optical component is attached to the holding portion. Further, in the optical component evaluation apparatus of the present invention, based on the evaluation result, it is possible to make an adjustment so that the optical axis shift between the optical components and the mounting error between the optical component and the frame are zero or sufficiently small.
Prior to the description of the embodiments of the present invention, the operational effects will be described in a general manner.
It is assumed that one optical component is held in a fixed state and the other optical component is held movably. At this time, it is assumed that the optical axis of one optical component does not match the optical axis of the other optical component. In this case, the center coordinates of the two transmitted light beam groups (the light beam that has passed through the first region group and the light beam that has passed through the second region group) transmitted through each optical component do not match. Therefore, the difference (distance) between the center coordinate of one transmitted light beam group and the center coordinate of the other transmitted light beam group is calculated as the amount of deviation of the optical axis in one optical component. Then, the movement amount of one optical component is obtained based on the calculated deviation amount of the optical axis. As described above, since the center coordinates of each transmitted light beam are used for calculating the deviation amount of the optical axis, the number of pixels in the population when calculating the center coordinates can be increased. As a result, it is possible to reduce variations in the center coordinates compared to the case where the number of pixels in the population is small. That is, the variation in evaluation value can be reduced. As a result, the detection resolution of the amount of deviation of the optical axis can be increased. Therefore, the optical axis can be adjusted with higher accuracy.

First Embodiment Hereinafter, a first embodiment will be described with reference to FIGS.
FIG. 1A is a schematic diagram of an optical axis adjusting device according to the present embodiment, FIG. 1B is an explanatory diagram of a chart 4 viewed in the AA direction in FIG. 1A, and FIG. 3 is a schematic diagram of pinhole images to be picked up, FIG. 3 is a schematic diagram of pinhole images constituting two light beams that have passed through the transmission hole, FIG. 4 is a schematic diagram illustrating the center coordinates of each light beam, and FIG. FIG. 5 is an explanatory diagram in which a central coordinate portion shown in FIG.

  In FIG. 1A, a pinhole plate 2 subjected to pinhole processing is arranged below the light source 1. A collimator lens 3 is disposed below the pinhole plate 2. A chart 4 is arranged below the collimator lens 3. The chart 4 is an opaque disk-shaped thin plate member, and is arranged so that its disk plane is perpendicular to the optical axis of the lens system 15 to be adjusted, which will be described later.

  As shown in FIG. 1B, chart 4 shows a transmission hole row R0 (first region group) and a transmission hole row R1 (second region) arranged concentrically with the circumference of the transmission hole row R0. Group). The transmission hole row R0 includes pinholes P01, P02, P03, P04, P05, P06, P07. P08 (plural regions) are formed by arranging eight points on the circumference at equal intervals. The transmission hole row R1 is formed by arranging eight pinholes P11, P12, P13, P14, P15, P16, P17, and P18 (a plurality of regions) at equal intervals on the circumference.

Here, although the pinholes P01 to P08 and P11 to P18 of the chart 4 may be formed by ordinary metal processing, it is preferable to perform processing by photoetching processing with higher processing accuracy than normal metal processing. Alternatively, it is preferable to form the pinholes P01 to P08 and P11 to P18 by forming the substrate in a parallel plane shape and performing pattern deposition with better processing accuracy than normal metal processing.
Photo-etching and pattern deposition are about two orders of magnitude better than normal metal processing. On the other hand, the processing accuracy of pinholes (transmission holes) provided on the substrate (alignment degree that aligns the circumference with high accuracy, concentricity of the two transmission holes, etc.) directly affects the accuracy of the evaluation value. Therefore, the substrate is produced by photoetching and pattern deposition. By doing in this way, the processing precision of a board | substrate can be improved and the precision of an evaluation value can be improved.

  In FIG. 1A, below the chart 4, an adjusted lens system 15 including a lens system 9, an aligning jig 8, a holding unit 6, and a moving unit 5 are provided. The aligning jig 8 is disposed so as to contact the lens system 9. The holding unit 6 holds the lens system 15 to be adjusted. The moving means 5 is disposed on the holding means 6. The aligning jig 8 is connected to the moving means 5. Therefore, the movement of the moving means 5 is transmitted to the adjusted lens system 9 via the aligning jig 8. The moving means 5 is configured to be able to move the aligning jig 8 in the XY direction orthogonal to the optical axis of the lens system 15 to be adjusted.

  The adjusted lens system 15 includes a frame 10 that holds the lens system 9 and the lens system 11. The holding means 6 holds the adjusted lens system 15 by holding the frame 10. Here, the lens system 11 is held in a state of being fixed to the frame 10 before the optical axis adjustment.

  The lens system 9 is held in a movable state by moving to the frame 10 before adjusting the optical axis. A space between the lens system 9 and the frame 10 is filled with an ultraviolet curable adhesive before adjusting the optical axis. The ultraviolet curable adhesive is cured by being irradiated with ultraviolet rays from an ultraviolet irradiation unit (not shown) after adjusting the optical axis. As a result, the lens system 9 is held (fixed).

  The frame 10 is held by the holding means 6. The frame 10 is arranged so that the centers of the transmission hole arrays R0 and R1 coincide with the optical axis of the lens system 11.

  In the present embodiment, the lens system 9 and the lens system 11 are held by the frame 10, but the holding unit of the present invention is not limited to this. The lens system 11 that is the first optical element (optical component) and the lens system 9 (optical component) that is the second optical element may be held by different holding units.

  In FIG. 1A, a CCD camera 12 is disposed below the lens system 15 to be adjusted. The CCD camera 12 is configured to be movable in the optical axis direction of the lens system 15 to be adjusted by the driving means 7. An arithmetic processing unit 14 for controlling the CCD camera 12, the driving unit 7, and the moving unit 5 is provided.

  The arithmetic processing unit 14 detects the coordinates of the two light beam groups transmitted through the two transmission hole arrays R0 and R1 and the lens system 15 to be adjusted. Specifically, the arithmetic processing unit 14 uses the image captured by the CCD camera 12 (the image of the light beam group transmitted through the two transmission hole arrays R0 and R1 and the lens system 5 to be adjusted) to provide two transmission holes. The center coordinates of the columns R0 and R1 (that is, the center coordinates of the circumference of each light beam group) are obtained. Then, the distance between the central coordinates is calculated, and the movement amount of the lens system 9 is calculated from the calculation result. Note that the images of the two light beam groups observed by the CCD camera 12 (observed images of the transmission hole arrays R0 and R1) are displayed on the display device 13.

  In the optical axis adjusting apparatus configured as described above, the light emitted from the light source 1 is transmitted through the pinhole plate 2 to create a point light source. The light from the point light source becomes a parallel light beam by the collimator lens 3. The parallel light beam irradiated from the collimator lens 3 is irradiated to the chart 4 provided with the transmission hole arrays R0 and R1. Then, the two transmitted light beam groups emitted from the chart 4 are irradiated to the lens system 15 to be adjusted. Two transmitted light flux groups transmitted through the lens system 15 to be adjusted are imaged by the CCD camera 12. An image obtained by this imaging is displayed on the display device 13.

  FIG. 3 is a schematic diagram of each pinhole image displayed on the display device 13. Each pinhole image constitutes a transmitted light beam group. As shown in FIG. 3, the display device 13 includes a transmitted light beam group Z0 including pinhole images Z01, Z02, Z03, Z04, Z05, Z06, Z07, and Z08, and pinhole images Z11, Z12, Z13, and Z14. , Z15, Z16, Z17, Z18, a transmitted light beam group Z1 is displayed. These pinhole images are obtained via the lens system 15 to be adjusted.

  The sizes of the above-described transmitted light beam groups Z0 and Z1 are adjusted so that the transmitted light beams Z0 and Z1 imaged by the CCD camera 12 are maximized in the field of view of the CCD camera 12. This adjustment is performed by moving the CCD camera 12 up and down in the optical axis direction of the lens system 15 to be adjusted by the driving means 7.

  Next, a method for calculating center coordinates by the arithmetic processing unit 14 will be described. In calculating the center coordinates, first, each barycentric coordinate is detected from each transmitted light beam imaged by the CCD camera 12. Subsequently, the center coordinates of each transmitted light beam group are calculated using the barycentric coordinates. In the calculation of the center coordinates, the sum of the barycentric coordinates of each light flux is obtained, and the average is obtained.

  The calculation of the center coordinates will be further described. The images of the two transmitted light beam groups Z0 and Z1 imaged (observed) by the CCD camera 12 are sent to the arithmetic processing unit 14. Here, the arithmetic processing unit 14 performs image processing on each pinhole image constituting the transmitted light beam groups Z0 and Z1. This image processing is performed by binarizing each pixel. In the binarization process, “1” is given to a pixel whose luminance is higher than a predetermined threshold value set in advance, and “0” is given to other pixels whose luminance is low.

Next, calculation of the movement amount of the lens system 9 will be described using images of the transmitted light beam groups Z0 and Z1 subjected to image processing.
For each pinhole image, an average of all the X coordinates X01 to X0n and Y coordinates Y01 to Y0n of the pixels that are “1” in the binarization processing is obtained, and the barycentric coordinates (Xc, Yc) is calculated (see the example of FIG. 2).

The barycentric coordinates of each pinhole image can be obtained from the following calculation formulas (1) and (2).
Xc = (total of X01 to X0n) / n (1)
Yc = (total of Y01 to Y0n) / n (2)
Using the calculation formulas (1) and (2), the center-of-gravity coordinates Zc01, Zc02, Zc03, Zc04, Zc05, Zc06, Zc07, Zc08, Zc11, Zc12, Zc13, Zc14, Zc15, Zc16, Zc17 of each pinhole image are used. , Zc18 is obtained. The calculated barycentric coordinates of each pinhole image are shown in parentheses of reference numerals of the pinhole images in FIG.

Using the center-of-gravity coordinates of each pinhole image shown in FIG. 3, the center coordinates Z0c and Z1c of the two transmitted light beam groups Z0 and Z1 are calculated using the following calculation formulas (3), (4), (5), (6 ) (See FIG. 4).
X coordinate of Z0c: Z0cX = (sum of X coordinates of Zc01 to Zc08) / 8 (3)
Y coordinate of Z0c: Z0cY = (total of Y coordinates of Zc01 to Zc08) / 8 (4)
Similarly,
X coordinate of Z1c: Z1cX = (total of X coordinates of Zc11 to Zc18) / 8 (5)
Y coordinate of Z1c: Z1cY = (total of Y coordinates of Zc11 to Zc18) / 8 (6)

Further, using the center coordinates Z0c and Z1c calculated by the calculation formulas (3) to (6), the distance between the center coordinates of the two transmitted light beams is obtained from the following formula (7) (see FIG. 5).
{(Z1cX-Z0cX) ² + (Z1cY-Z0cY) ² } ^1/2 (7)
The correction movement amount is obtained according to the distance between the center coordinates obtained from the calculation formula (7). Here, the corrected movement amount means a value obtained by multiplying the obtained distance between the center coordinates by a constant k. The constant k is an inclination obtained from an approximate straight line in which the distance between the center coordinates is given on the graph by giving a deviation of the optical axis between the lens system 9 and the lens system 11, and for each lens to be adjusted. The value set to. This correction movement amount is calculated by the arithmetic processing unit 14 in the same manner as the above calculations. This corrected movement amount becomes the final movement amount (evaluation value) of the lens system 9.

Next, a method of moving the lens system 9 based on the evaluation value of the center coordinate so that the optical axis of the lens system 9, the optical axis of the optical system of the optical system of the lens system 11 and the optical axis adjusting device will be described.
The moving means 5 moves based on the corrected movement amount (evaluation value) calculated by the arithmetic processing unit 14. The movement of the moving means 5 is transmitted to the lens system 9 via the aligning jig 8, and the lens system 9 moves. After the movement, the lens system 9 is fixed to the frame 10. At the time of fixing, ultraviolet rays are irradiated from an ultraviolet irradiation unit (not shown) to cure the ultraviolet curable adhesive.
In the above description, it is assumed that the optical axis shift (or the attachment error between the optical component and the frame) can be made zero or sufficiently small by one movement of the lens system 9. However, there may be a case where the optical axis deviation (or the attachment error between the optical component and the frame) cannot be reduced to zero or sufficiently small by one movement. Therefore, a standard may be set in advance, and the lens system 9 may be moved until the evaluation value falls within this standard. That is, the position adjustment of the lens system 9 is repeatedly performed by the moving unit 5 so that the evaluation value falls within a preset standard. Then, in order to fix the lens system 9 to the frame 10 when it falls within the standard, ultraviolet rays are irradiated from an ultraviolet irradiation unit (not shown) to cure the ultraviolet curable adhesive.

Next, various configuration examples of the substrate according to the present invention will be described.
FIG. 6 is a diagram showing a configuration example of a chart as the substrate.
The chart 20 shown in FIG. 6 has a ring-shaped transmission hole T1 instead of the pinholes P01 to P8 in the chart 4 and a ring-shaped transmission arranged concentrically with the transmission hole T1 instead of the pinholes P11 to P18. And a hole T2. Here, the transmission holes T1 and T2 in the chart 20 have the center of gravity of each hole on the same circumference.
By using this chart 20 in place of the chart 4 in FIG. 1A, the same effects as when the chart 4 is used can be obtained.

FIG. 7 is a diagram showing still another configuration example of the chart as the substrate, and shows an example of a chart in which the first transmission hole and the second transmission hole are formed by four or more holes.
In FIG. 7, a chart 21 includes eight holes forming inner transmission holes arranged concentrically with the circumference of the chart 21, and outer transmission holes arranged concentrically with the inner transmission holes. And eight holes to be formed. Each hole is formed in a rectangular shape as shown in FIG. Here, the first transmission hole and the second transmission hole in the chart 21 have the center of gravity of each hole on the same circumference.
When this chart 21 is used in place of the chart 4 in FIG. 1A, two light beams that have passed through the chart 21 and have a rectangular parallelepiped shape can be obtained, and the same effects as when the chart 4 is used. Can be obtained.

FIG. 8 is a diagram showing still another configuration example of the chart as the substrate, and an example of a chart provided with a circumference variable mechanism capable of changing the circumference size of the light beam imaged by the imaging device. Is shown.
8 includes a plurality of fixing screws 23, a plurality of diaphragm plates 24 fixed to the chart 22 by tightening the fixing screws 23, and a plurality of diaphragm plates 25 that are vertically longer than the diaphragm plate 24. have.

The diaphragm plate 24 is an elongated rectangular thin plate member having a rectangular hole at one end in the longitudinal direction and a fixing screw locking hole 29 at the other end in the longitudinal direction. The fixing screw locking hole 29 is formed in a flat elliptical shape that is long in the longitudinal direction of the diaphragm plate 24, and the width thereof is formed to be approximately the same as the diameter of the fixing screw 23.
The diaphragm plate 24 is arranged on the chart with the hole directed toward the center point of the chart 22 and the fixing screw locking hole 29 directed toward the outer periphery of the chart 22. Then, by moving the diaphragm plate 24 in the direction indicated by the arrow in FIG. 8, the size of the circumference of the light beam forming the inner transmission hole can be changed.

The diaphragm plate 25 is an elongated rectangular thin plate member that is longer in the longitudinal direction than the diaphragm plate 24. The diaphragm plate 25 has a hole having the same configuration as the rectangular hole of the diaphragm plate 24 and a fixing screw locking hole 29 having the same configuration as the fixing screw locking hole 29 of the diaphragm plate 24.
Similar to the diaphragm plate 24, the diaphragm plate 25 is arranged on the chart with the hole directed toward the center of the chart 22 and the fixing screw locking hole directed toward the outer periphery of the chart 22. Then, by moving the diaphragm plate 25 in the direction indicated by the arrow in FIG. 8, the size of the circumference of the light beam forming the outer transmission hole can be changed.

  The chart 22 corresponds to the fixing screw locking holes 29 of the diaphragm plates 24 and 25 on the circumference of the chart 22 at positions where the fixing screw locking holes 29 are fixed by the fixing screws 23. A fitting hole (not shown) having a diameter substantially equal to the diameter is provided. Further, the chart 22 has a plurality of gaps (not shown) corresponding to positions where the holes of the diaphragm plates 24 and 25 can move.

In order to change the size of the circumference of each transmission hole using the chart 22, the diaphragm plates 24 and 25 are arranged at arbitrary positions on the chart 22, and the fixing screws 23 are tightened to tighten the diaphragm plates 24. , 25 are fixed on the chart 22.
By using the chart 22 configured as described above instead of the chart 4 in FIG. 1A, the same operational effects as those when the chart 4 is used can be obtained.
The fitting hole provided in the chart 22 has a diameter substantially equal to the diameter of the fixing screw, and the gap provided in the chart 22 is closed by one of the diaphragm plates 24 and 25. Therefore, when the light beam is irradiated onto the chart 22, the light beam passes only through the holes of the diaphragm plates 24 and 25, and two light beams necessary for calculating the movement amount of the lens system 9 are obtained.
In this way, if the size of the circumference of the two transmission holes can be made variable, the optical axis can be adjusted when the lens system is adjusted to have a different diameter. It can correspond to.

FIG. 9 is a diagram showing a configuration of a hole diameter variable mechanism that can change the size of each of the first transmission holes and the second transmission holes in the charts shown in FIGS. 7 and 8.
In FIG. 9, the transmission hole plate 26 is formed in a substantially L shape obtained by bending an elongated plate member. The transmission hole plate 26 has a through hole 30 for a fixing screw 28 for fixing the transmission hole plate 26 and the chart at the approximate center of the bent portion. The through hole 30 of the transmission hole plate 26 is formed in a flat oval shape whose vertical length is shorter than the width of the transmission hole plate, and the width of the through hole 30 is formed to be approximately the same as the diameter of the fixing screw 28. ing.
The transmission hole plate 27 is formed in a substantially inverted L shape obtained by bending an elongated plate-like member similar to the transmission hole plate 26 in the direction opposite to the transmission hole plate 26, and the transmission hole plate 27 has a transparent portion in the center of the bent portion. A through hole 30 similar to the through hole 30 of the hole plate 26 is provided.
The chart (not shown) on which the transmission hole plates 26 and 27 are arranged is provided with a locking hole (not shown) for locking the fixing screw 28.
The transmission hole plates 26 and 27 are only locked at their respective bent portions by a single fixing screw 28, but the frictional force on the surface where the transmission hole plate 26 and the transmission hole plate 27 are in contact with each other and the chart Due to the frictional force of the surface in contact with the transmission hole plate 26, the transmission hole plates 26 and 27 are prevented from shifting on the chart.

In order to change the size of the transmission hole using the transparent hole plate 26, the fixing screw 28 that locks the transmission hole plate 26 to the chart is loosened on the chart, and the transmission hole plate 26 is changed to the one shown in FIG. The permeation hole plate 26 is moved in the direction of the arrow shown on the right side, and the permeation hole plate 26 is fixed at the position of the desired permeation hole diameter. In order to change the size of the transmission hole using the transmission hole plate 27, the transmission hole plate 27 is moved in the arrow direction shown on the left side of FIG. Note that both the transmission hole plates 26 and 27 may be moved to adjust the size of the transmission holes.
Here, the direction in which the transmission hole plates 26 and 27 are movable is limited to the radial direction of the chart by the locking holes of the chart, the through holes 30 of the transmission hole plates 26 and 27, and the fixing screws 28. The transmission holes obtained as a result of moving the transmission hole plates 26 and 27 are also positioned on concentric circles centered on the central coordinates of the chart.
Thus, by moving the transmission hole plates 26 and 27, the size of the transmission hole shown in FIG. 7 or FIG. 8 can be changed while holding each transmission hole in a concentric shape with the center coordinates as the center. it can.
As described above, when the hole diameter variable mechanism is provided, the optical axis can be adjusted without changing the substrate for each lens system to be adjusted even if the lens system to be adjusted is changed.

  FIG. 10 is a diagram showing another configuration example of the chart as the substrate. In this configuration example, the substrate has a transmission hole row R0 and a transmission hole row R1, and is arranged so that the center coordinates of the transmission hole row R0 and the center coordinates of the transmission hole row R1 coincide. The transmission hole rows R0 and R1 are arranged in a rectangular shape. By using this chart 31 in place of the chart 4 in FIG. 1A, the same effect as when the chart 4 is used can be obtained.

FIG. 11 is a diagram showing still another configuration example of the chart as the substrate. In this configuration example, the pattern of the transmission holes arranged on the substrate is a combination of the transmission hole array R0 arranged in a circular shape and the transmission hole array R1 arranged in a rectangular shape. Here, the two transmission hole rows are arranged so that the center coordinates of the transmission hole row R0 and the center coordinates of the transmission hole row R1 coincide.
By using this chart 32 in place of the chart 4 in FIG. 1A, the same effect as when the chart 4 is used can be obtained.

FIG. 12 is a diagram showing still another configuration example of the chart as the substrate. In this configuration example, three pinholes constituting the transmission hole array R0 arranged on the substrate are arranged at equiangular intervals on a concentric circle. Similarly, three pinholes are arranged on the concentric circles at equiangular intervals in the transmission hole row R1. Here, the two transmission hole rows are arranged so that the center coordinates of the transmission hole row R0 and the center coordinates of the transmission hole row R1 coincide.
By using this chart 33 in place of the chart 4 in FIG. 1A, the same effects as when the chart 4 is used can be obtained.

Second Embodiment Next, a second embodiment will be described with reference to FIGS.
FIG. 13 is a schematic configuration diagram of an optical axis adjusting apparatus according to the present embodiment, and FIG. 14 is a detailed diagram of a chart used in the present embodiment.
This embodiment is different from the first embodiment in that a light source 4 ′ having a plurality of light emitting portions is arranged instead of the light source 1, the pinhole plate 2, the collimator lens 3 and the chart 4. Yes. Other configurations are the same as those of the first embodiment.

As shown in FIG. 14, the light source 4 ′ is configured by arranging a plurality of light emitting units on a substrate 23. The light source 4 ′ has a light beam ring L0 and a light beam ring L1 arranged concentrically with the light beam ring L0.
As shown in FIG. 14A, the luminous flux ring L0 is formed by arranging eight light emitting portions L01, L02, L03, L04, L05, L06, L07, and L08 at equal intervals on the same circumference. Yes. The light beam ring L1 is formed by arranging eight light emitting portions L11, L12, L13, L14, L15, L16, L17, and L18 at equal intervals on the circumference concentric with the light beam ring L0. The light emitting part constituting each light beam ring is composed of light emitting elements such as LEDs and LDs, and the emitted light beam becomes a parallel light beam. In order to obtain a parallel light beam, a lens may be disposed on the light exit side of the light emitting element.

In this embodiment, the same operations and effects as those of the first embodiment including the light source 1, the pinhole plate 2, the collimator lens 3, and the chart 4 can be obtained.
In the present embodiment, the two light flux rings are concentrically arranged, but the same operation and effect can be obtained even if the light emitting portion is arranged as in the charts shown in FIGS. .

  As is clear from the above description, according to the present embodiment, since the center coordinates of the transmitted light beams Z0 and Z1 are used for calculation of the detection value, the dispersion of the respective points can be offset, and the dispersion of the center coordinates is reduced. Can be small. That is, variations in detection values can be suppressed, and high detection resolution can be realized. As a result, the optical axis can be adjusted in a small lens unit with severe optical axis deviation accuracy, which can contribute to the miniaturization of the lens unit.

  According to the present invention, the adjusted lens system is irradiated with the light beam transmitted through the two transmission regions, the transmitted light beam is observed, and the center coordinates of the two transmission regions are used for calculating the detection value. The center coordinates of the two transmissive areas are calculated by taking the sum of the coordinates of the light beams that have passed through the transmissive area and averaging them. Thereby, the variation of each light beam is canceled out, and the variation of the center coordinates can be made smaller than the variation of one point of the light beam.

(A) is a schematic block diagram of 1st Example of the optical-axis adjustment apparatus by this invention, (b) is explanatory drawing of the chart 4 seen along the AA line of (a). It is a schematic diagram of the observed pinhole image. It is a schematic diagram of each pinhole image which comprises the observed transmitted light beam. It is the schematic diagram showing the center coordinate of the transmitted light beam. It is explanatory drawing which expanded the center coordinate part of FIG. It is a figure which shows the chart comprised from the belt | band | zone on the circumference. It is a figure which shows the chart from which the permeation | transmission hole was comprised from the rectangular-shaped hole. It is a figure which shows the chart which can change the magnitude | size of a circumference. It is a figure which shows the structure of the hole diameter variable mechanism which can change the magnitude | size of each hole of a permeation hole. It is a top view which shows the example of 1 structure of a chart. It is a top view which shows the other structural example of a chart. It is a top view which shows the other structural example of a chart. It is a schematic block diagram of 2nd Example of the optical axis adjustment apparatus by this invention. (A) is a top view of the chart used for 2nd Example, (b) is a side view of (a) which abbreviate | omits and shows a part of light emission part. It is a schematic block diagram of the conventional optical axis adjustment apparatus. It is explanatory drawing regarding the image formation of the conventional optical axis adjustment apparatus. It is a figure which shows the image in the CCD camera image-receiving surface of the conventional optical axis adjustment apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,50 Light source 2,51 Pinhole plate 3,53 Collimator lens 4,4 ', 55 Chart 5 Moving means 6 Holding means 7 Driving means 8 Alignment jig 9,11 Lens system 10 Frame 12,63 CCD camera 13 Display Device 14, 66 Arithmetic processing unit 15 Adjustable lens system 20, 21, 22, 31, 32, 33, 34 Substrate 23 Fixing screw 24, 25 Diaphragm plate 26, 27 Transmission hole plate 28 Fixing screw 29 Fixing screw locking hole DESCRIPTION OF SYMBOLS 30 Through-hole 52 ND filter 54 Mirror 56,59 Lens system 57 Ball frame 58 Mounting part 60 Adjustment jig 61 Image surface 62 Microscope lens 64 Focus axis 65 Coarse alignment biaxial 67 Irradiation point 68 Center of gravity 69 Fine alignment biaxial P01- P08, P11 to P18 Pinhole R0, R1 Transmission hole array Z01 to Z08, Z11 to Z18 Pinhole image Z0, Z1 Transmission Light beam group L0, L1 Light beam ring L01-L08, L11-L18

Claims (18)

A light flux generating section for generating a plurality of light fluxes;
An imaging device disposed at a position to receive light from the light flux generation unit;
A holding member that is disposed closer to the light flux generation unit than the imaging device and holds an optical component;
A processing device that performs predetermined processing based on output information from the imaging device,
The light flux generation unit has at least a first region group and a second region group,
The plurality of regions in the first region group are located apart from each other on the first predetermined line,
The plurality of regions in the second region group are located apart from each other on a second predetermined line,
The second region group is located outside the first region group,
The output information is obtained from information on the center position of the first region group obtained from the images of the plurality of regions in the first region group and the images of the plurality of regions in the second region group. In addition , information on the center position of the second region group is included,
The processing device calculates a movement amount of the optical component necessary for position adjustment of the optical component based on information on a center position of the first region group and information on a center position of the second region group. To do,
An optical component evaluation apparatus. The luminous flux generation unit has a light source and a substrate,
The substrate is disposed between the light source and the holding member, or between the holding member and the imaging device,
The plurality of regions in the first region group and the second region group are regions that transmit or reflect light.
The optical component evaluation apparatus according to claim 1. The luminous flux generation unit is a light source having a plurality of light emitting units,
The plurality of regions in the first region group and the second region group are the plurality of light emitting units, and are arranged at equal intervals on the first predetermined line and the second predetermined line. ,
The optical component evaluation apparatus according to claim 1.   The optical component evaluation apparatus according to any one of claims 1 to 3, wherein the first predetermined line is a circumference.   The optical component evaluation apparatus according to any one of claims 1 to 3, wherein the first predetermined line is a polygonal side.   The optical component evaluation apparatus according to any one of claims 1 to 3, wherein the second predetermined line is a circumference.   The optical component evaluation apparatus according to any one of claims 1 to 3, wherein the second predetermined line is a polygonal side.   4. The optical component evaluation apparatus according to claim 1, wherein outer shapes of the plurality of regions in the first region group are all the same. 5.   4. The optical component evaluation apparatus according to claim 1, wherein outer shapes of the plurality of regions in the first region group include at least two different shapes. 5.   4. The optical component evaluation apparatus according to claim 1, wherein outer shapes of the plurality of regions in the second region group are all the same. 5.   4. The optical component evaluation apparatus according to claim 1, wherein outer shapes of the plurality of regions in the second region group include at least two different shapes. 5.   4. The optical component evaluation apparatus according to claim 1, wherein an outer shape of each of the plurality of regions is a circle. 5.   The optical component evaluation apparatus according to claim 1, wherein an outer shape of the plurality of regions is a polygon. Information of the center position before Symbol first area group is information obtained by calculating an average value of all the barycentric coordinates of the image of the plurality of regions in said first area group,
The information on the center position of the second region group is information obtained by calculating an average value of all barycentric coordinates of the images of the plurality of regions in the second region group. The optical component evaluation apparatus described in 1. The optical device evaluation apparatus according to any one of claims 1 to 14,
A moving means for moving in a direction orthogonal to the optical axis of the optical component based on information necessary for position adjustment of the optical component calculated by the processing device;
An alignment jig arranged to contact the optical component and configured to be connected to the moving means;
Optical axis adjusting device, characterized in that it comprises a. A first region group consisting of a plurality of regions positioned apart from each other on a first predetermined line and a plurality of regions positioned outside the first region group and positioned apart from each other on a second predetermined line An imaging step of imaging a second area group of areas via an optical component;
Was determined from an image of a plurality of regions in said first area group, and information of the center position of the first area group was determined from images of a plurality of regions in the second area group, the second group of regions A calculation step for calculating a movement amount of the optical component necessary for position adjustment of the optical component based on information on a center position ;
The evaluation method of the optical component characterized by including. The information on the center position of the first region group is information obtained by calculating an average value of all barycentric coordinates of images of a plurality of regions in the first region group,
The information on the center position of the second area group is information obtained by calculating an average value of all barycentric coordinates of images of a plurality of areas in the second area group. The evaluation method of the optical component as described. 18. The method according to claim 16, further comprising a step of adjusting the position of the optical component based on a movement amount of the optical component necessary for adjusting the position of the optical component calculated in the calculating step. Evaluation method for optical parts.