JP5775741B2 - Shape measuring method, processing method using the same, and shape measuring apparatus - Google Patents

Description

  The present invention relates to a shape measuring method, a processing method using the same, and a shape measuring apparatus.

Conventionally, as a shape measuring method for measuring a surface shape formed by processing a workpiece, measurement data of the surface shape is measured as a deviation from a design value of the surface shape. In this shape measurement method, in order to correct the measurement error caused by the error of the workpiece holding position in the shape error measuring device, the entire measurement data is subjected to coordinate conversion consisting of parallel movement and rotational movement, and the design value is obtained. The position of the measurement data is corrected (alignment correction) so that the deviation from the minimum is obtained, and the deviation between the corrected measurement data and the design value is obtained as a shape error.
In a shape measuring apparatus using such a shape measuring method, it is necessary to store in advance information on the design value of the surface shape of the workpiece. At this time, if the surface shape is a complicated configuration, a general-purpose shape measuring device cannot input a design formula, and thus a dedicated shape measuring device is required.
For this reason, for example, in Patent Document 1, a measurement unit that detects the shape of a measurement object processed based on a shape design formula, and measurement shape data obtained by the measurement unit are input to input the measurement object surface. And an arithmetic processing unit having a data processing means for obtaining a difference between the design shape data based on the shape design formula and the data processing means for calculating the design shape data based on the shape design formula incorporated in advance. A library unit for storing the library file, a calculation unit for reading the library file from the library unit and calculating a difference between the measurement shape data input from the measurement unit and the design shape data, and the calculation unit from the library unit The design parameter input section gives the design parameter values to the library file loaded into the library file. A design formula creating means capable of defining a new shape design formula other than the shape design formula incorporated in the section and creating the library file, and a library file created by the design formula creating means, It is configured so that it can be stored in the library section, and the library file for calculating the design shape data includes a partial differential expression of the shape design expression or an approximate calculation expression for calculating an approximate value of the partial differential expression. A shape measuring device is described.
In this shape measuring apparatus, design shape data based on the shape design formula and a partial differential formula of the shape design formula can be stored in the library unit, so that the surface shape is represented by an appropriate shape design formula. However, the shape error can be measured by performing position correction using the position correction function of the shape measuring apparatus.

Japanese Patent No. 4446272

However, the conventional shape measuring method as described above has the following problems.
In the technique described in Patent Document 1, when the surface shape is expressed by one shape design formula (function), the user can incorporate an original design formula. When expressed by a plurality of shape design formulas (functions), there is a problem that measurement cannot be performed because the surface shape cannot be set by a combination of the plurality of shape design formulas (functions).

  The present invention has been made in view of the above problems. Even when the design value of the surface shape of the object to be measured is defined by a plurality of functions, the measurement data is subjected to alignment correction after being subjected to alignment correction. It is an object of the present invention to provide a shape measuring method, a processing method using the shape measuring method, and a shape measuring device that can be measured as a deviation amount from the design value of the surface shape of the measuring body.

In order to solve the above-mentioned problem, in the invention according to claim 1, there is provided a shape measuring method for measuring the surface shape of the object to be measured, wherein the shape defining step defines the design value of the surface shape by a plurality of functions. A data acquisition step of measuring the surface shape and acquiring measurement data of the surface shape, a data partitioning step of partitioning the measurement data into subgroups for each domain of the function, and for each subgroup an analysis step of estimating a movement parameter which represents the amount of deviation from the design value of the surface shape, by performing the alignment correction of the measurement data using the moving parameters estimated by the analysis step, generates a corrected measurement data And a shape error calculating step of calculating a deviation between the corrected measurement data and the plurality of functions as a shape error.

  According to a second aspect of the present invention, in the shape measuring method according to the first aspect, two partial groups adjacent to each other and connected at a boundary among the partial groups are defined as a first partial group and a second partial group. The analysis step and the alignment correction step are performed on the first and second subgroups, with the boundary in the first subgroup being referred to as the end point and the boundary in the second subgroup being referred to as the start point. Are referred to as the first and second analysis steps and the first and second alignment correction steps, respectively, after the first analysis step and the first alignment correction step are performed in this order, the starting point is aligned. The coordinate data of the measurement data of the second subgroup is changed so that it matches the end point after correction and the differential coefficient at the start point matches the differential coefficient at the end point after alignment correction. A data conversion step is performed, and the second analysis step and the second alignment correction step are performed in this order on the measurement data of the second partial group after the coordinate conversion is performed in the data conversion step. In this case, the shape error calculation step is performed after the second alignment correction step.

  According to a third aspect of the present invention, in the shape measurement method according to the second aspect, between the second alignment correction step and the shape error calculation step, a differential coefficient at the end point subjected to alignment correction, and an alignment A convergence determination step of calculating a slope deviation due to a difference from the corrected differential coefficient at the starting point and determining whether the slope deviation is equal to or less than a preset allowable value is provided. In the convergence determination step, the slope deviation is The shape error calculating step is performed when the value is equal to or less than an allowable value, and when the inclination deviation exceeds the allowable value, the data conversion step, the second step are performed based on the measurement data in the convergence determination step. The analysis step, the second alignment correction step, and the convergence determination step are repeated in this order.

According to a fourth aspect of the present invention, there is provided a shape measuring method for measuring a surface shape of an object to be measured, a shape defining step for defining a design value of the surface shape by a plurality of functions, and measuring the surface shape. A data acquisition step of acquiring measurement data of the surface shape, a data partitioning step of dividing the measurement data into subgroups for each domain of the function, and the function and the measurement data for each of the subgroups. By performing a least-squares calculation that minimizes the residual sum of squares with all residual sums of squares added, a movement parameter that represents the amount of deviation from the design value of the surface shape is a value common to all of the subgroups. an analysis step of estimating a, performs alignment correction of the measurement data using the moving parameters estimated by the analysis step, the alignment correction step of generating the corrected measurement data, the A shape error calculating step of calculating a deviation between Seisumi measurement data and the plurality of functions as shape error, the method comprising.

In the invention described in claim 5, in the processing method, the workpiece surface shape of the forming target is defined by a plurality of functions by processing any of claims 1-4 to the workpiece as the object to be measured or by the shape measuring method according to item 1, wherein the measured shape error with respect to the surface shape of the processing target of the workpiece, when the shape error exceeds a preset allowable value, modifying the shape error In this way, the workpiece is reprocessed.

The invention according to claim 6 is a shape measuring device for measuring the surface shape of the object to be measured, wherein the function storage unit stores information on a plurality of functions defining design values of the surface shape, and the device to be measured A measurement data generation unit that measures the surface shape of the body and generates measurement data of the surface shape; a data acquisition unit that acquires the measurement data; and divides the measurement data into subgroups for each domain of the function A data partition unit, an analysis unit for estimating a movement parameter indicating a movement amount when the surface shape is obtained by movement from the corresponding function for each of the subgroups , and the movement estimated by the analysis unit Alignment correction of the measurement data using parameters to generate corrected measurement data, and deviation between the corrected measurement data and the plurality of functions as a shape error The shape error calculating unit for output, and configured to include a.
The invention according to claim 7 is a shape measuring device for measuring the surface shape of the object to be measured, the function storage unit storing information of a plurality of functions that define design values of the surface shape, and the device to be measured A measurement data generation unit that measures the surface shape of the body and generates measurement data of the surface shape; a data acquisition unit that acquires the measurement data; and divides the measurement data into subgroups for each domain of the function Corresponding to the surface shape by performing a least squares calculation that minimizes the sum of squares of residuals by adding all of the squares of residuals using the data partition and the function for each of the subgroups and the measurement data Using an analysis unit that estimates a movement parameter representing a movement amount when obtained from movement from the function as a value common to all the subgroups, and the movement parameter estimated by the analysis unit A configuration comprising: an alignment correction unit that performs alignment correction of the measurement data to generate corrected measurement data; and a shape error calculation unit that calculates a deviation between the corrected measurement data and the plurality of functions as a shape error And

  According to the shape measuring method and the shape measuring apparatus of the present invention, the measurement data is divided into subgroups for each of the plurality of function domains, and the movement amount of each subgroup corresponding to the corresponding function is estimated. Therefore, even when the design value of the surface shape of the object to be measured is defined by multiple functions, the design value of the surface shape of the object to be measured should be corrected after the alignment correction of the measurement data. There is an effect that it can be measured as a deviation amount from the distance.

It is a typical front view showing a schematic structure of a shape measuring device concerning a 1st embodiment of the present invention. It is a functional block diagram which shows the function structure of the control unit of the shape measuring apparatus which concerns on the 1st Embodiment of this invention. It is typical sectional drawing which shows an example of the to-be-measured body measured with the shape measuring apparatus which concerns on the 1st Embodiment of this invention, and the typical graph showing the surface shape of the 1st surface of a to-be-measured body. It is a flowchart which shows the process flow of the shape measuring method which concerns on the 1st Embodiment of this invention. It is a typical graph explaining the analysis process and alignment correction process of the shape measuring method which concerns on the 1st Embodiment of this invention. It is a typical top view showing a schematic structure of a processing device used for a processing method concerning a 1st embodiment of the present invention. 5 is a schematic graph illustrating an example of shape error data obtained by the shape measuring method according to the first embodiment of the present invention, and a schematic graph illustrating an example of how to obtain machining data. It is a flowchart which shows the process flow of the shape measuring method which concerns on the 2nd Embodiment of this invention.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
In all the drawings, even if the embodiments are different, the same or corresponding members are denoted by the same reference numerals, and common description is omitted.

[First Embodiment]
A shape measuring apparatus according to a first embodiment of the present invention will be described.
FIG. 1 is a schematic front view showing a schematic configuration of a shape measuring apparatus used in the shape measuring method according to the first embodiment of the present invention. FIG. 2 is a functional block diagram showing a functional configuration of a control unit of the shape measuring apparatus used in the shape measuring method according to the first embodiment of the present invention. Fig.3 (a) is typical sectional drawing which shows an example of the to-be-measured object used for the shape measuring method which concerns on the 1st Embodiment of this invention. FIG. 3B is a schematic graph showing the surface shape of the first surface of the measurement object.

  As shown in FIG. 1, the shape measuring apparatus 50 according to the present embodiment includes a base 20, a measured object support unit 1, a first position detection unit 9, a support base unit 3, and a measurement unit 7. As shown in FIG. 4, a control unit 8 for controlling the measuring operation of the shape measuring apparatus 50 is provided.

The base 20 is a base member that supports the measured object support 1, the first position detector 5, and the support 3 on a horizontal surface on a flat upper surface.
Below, when referring to the relative position in the shape measuring apparatus 50, it may be described using an xyz coordinate system used for shape measurement. This xyz coordinate system is a coordinate system in which the vertical axis is the y-axis and the horizontal plane parallel to the upper surface of the base 20 is the zx plane. In FIG. 1, the z-axis is the left-right direction on the paper surface, the x-axis is the vertical direction on the paper surface, the positive z-axis direction is from left to right, and the positive x-axis direction is from the front side to the back side of the paper surface. is there.

The measured object support unit 1 holds the measured object 2 and supports it to be movable in the direction along the x-axis.
The schematic configuration of the measured object support unit 1 is as follows. A holding base that holds the measured object 2 from the outside in the radial direction and holds the reference axis P determined by the center axis of the outer shape of the measured object 2 in a posture parallel to the z axis. 1 a, a movable body 1 b that fixes the holding base 1 a on the side surface and moves the holding base 1 a along the x axis, and a movable body 1 b that is electrically connected to the control unit 8 according to a control signal from the control unit 8. And a drive mechanism 1c for driving.
As the drive mechanism 1c, an appropriate linear motion mechanism can be adopted. For example, a configuration including a screw feed mechanism and a motor, or a linear motion mechanism such as a linear motor can be employed.

The member to be measured 2 is not particularly limited as long as it is a member whose surface shape is represented by a plurality of functions and can measure the surface shape. Here, “represented by multiple functions” means a combination of functions that represent different surface shapes, and the domain of the function that represents the surface shape can be partitioned into multiple domains corresponding to these different functions. Means. For example, the step function U (x) is mathematically regarded as one function, but U (x) = 0 when the domain x <0, and U (x) = 1 when the domain x ≧ 0. Therefore, in this specification, two different constant functions are considered. The same applies to a case where a step function or the like is used to formally write one function form.
Specific examples of the measurement object 2 include an optical element such as a lens and a mold for molding an optical element such as a lens.
Further, the shape of the measurement surface of the measurement object 2 is not particularly limited.

In the following, a case of the lens shown in FIG.
The DUT 2 has a first surface 2A made of a convex surface and a second surface 2B made of a convex surface, and an annular flange portion 2C is formed on the outer peripheral side thereof. The side surface of the flange portion 2 </ b> C is formed as a cylindrical surface with good accuracy, and constitutes the reference outer shape in the radial direction of the measurement object 2. The central axis of the reference outline constitutes the reference axis P of the measurement object 2.
In the processing of the measurement object 2, centering is performed so as to be coaxial with the optical axis O of the first surface 2A and the second surface 2B and the reference axis P, but between the reference axis P and the optical axis O, There are shift and tilt shifts due to processing errors.

The first surface 2A is a lens surface 2a formed within a circle of diameter d ₀ around the optical axis O, the inside diameter d ₀ is extended by a distance r in the outer peripheral side from the diameter D _0, the outer diameter d _{1 =} d _The connection surface 2b is formed in an annular region of ₀ + 2r, and the flange surface 2c has a diameter d ₂ (where d ₂ > d ₁ ), which is an end surface of the flange portion 2C.
Lens surface 2a is a convex surface shape is represented in cross section including the optical axis O by one of the function f (x), the diameter d ₀ is in the effective lens diameter. As the function f (x), for example, a function representing a spherical surface or a rotationally symmetric aspheric surface can be employed. In FIG. 3A, the point d indicates the top of the lens surface 2a.
The flange surface 2c is a plane orthogonal to the optical axis O.
The connection surface 2b is a curved surface that connects the lens surface 2a and the flange surface 2c, and is represented by one function g (x). In the present embodiment, the lens surface 2a and the flange surface 2 are smoothly connected.
That is, if the boundary point between the flange surface 2c and the connection surface 2b in the cross section including the optical axis O is the point b, f, and the boundary point between the connection surface 2b and the lens surface 2a is the point c, e, the point b, In f, c, and e, the inclination of the tangent line changes continuously. Points a and g indicate points at the outermost position of the flange surface 2c.

Therefore, in the xyz coordinate system set in the shape measuring apparatus 50, the first surface 2A in the cross section in the horizontal direction (the direction along the zx plane) of the measurement object 2 when the optical axis O is aligned with the z axis. As shown in FIG. 3B, the surface shape z is expressed by the following equation (1) using differentiable functions f (x), g (x), and h (x), as shown in FIG. , (2a), (2b), (3a), and (3b). However, the parentheses represent the definition areas D _A , D _B1 , D _B2 , D _C1 , D _C2 .
The function h (x) is a constant function in the present embodiment.
In FIG. 3B, points q _a , q _b , q _c , q _d , q _e , q _f , and q _g on the graph are respectively points a, b, c, d, and e in FIG. , F, and g.

z = f (x) (D _A = {x | −X ₀ ≦ x ≦ X ₀ }) (1)
z = g (x) (D _B1 = {x | X ₀ ≦ x ≦ X ₁ }) (2a)
z = g (x) (D _B2 = {x | −X ₁ ≦ x ≦ −X ₀ }) (2b)
z = Z ₂ (= h (x)) (D _C1 = {x | X ₁ ≦ x ≦ X ₂ }) (3a)
z = Z ₂ (= h (x)) (D _C2 = {x | −X ₂ ≦ x ≦ −X ₁ }) (3b)
_{X 0 = d 0/2 ···} (4)
X ₁ = d _1/2 (5)
_{X 2 = d 2/2 ···} (6)

  Further, when the derivatives of the functions f (x), g (x), and h (x) are expressed as f ′ (x), g ′ (x), and h ′ (x), respectively, a condition for smoothly connecting at the boundary Is that the differential coefficients at the boundaries coincide. This condition is expressed by the following equations (7a), (7b), (8a), and (8b). Since each derivative is known, the value of each derivative is also known.

f ′ (X ₀ ) = g ′ (X ₀ ) (7a)
f ′ (− X ₀ ) = g ′ (− X ₀ ) (7b)
g ′ (X ₁ ) = h ′ (X ₁ ) (8a)
g ′ (− X ₁ ) = h ′ (− X ₁ ) (8b)

  For example, when the lens surface 2a is a rotationally symmetric aspherical surface, the function f (x) is expressed by the following equation (9).

Here, C ₀ is a curvature radius constant that is the reciprocal of the paraxial curvature radius, K is a conic constant, N is the number of aspheric coefficients, 2N is an aspheric order, C ₂ ,..., C _2N are aspheric coefficients. .
Here, an example of an axially symmetric aspherical expression using only even-order aspherical coefficients has been given. For example, an axially symmetric aspherical expression in which an odd term is entered as C _2i-1 | x | ^2i-1 May be adopted.

  Similarly, the second surface 2B has a surface shape represented by a plurality of functions, but detailed description of the second surface 2B is omitted.

The first position detector 9 detects the position of the measurement object 2 held by the measurement object support 1 in the x-axis direction. The position of the measurement object 2 can be detected, for example, by detecting the movement position of the moving body 1b to which the holding base 1a is fixed. As a specific example of the first position detection unit 9, for example, a combination of an optical scale and a scale reading sensor, a laser length measuring device, or the like can be employed.
The first position detection unit 9 is electrically connected to the control unit 8 and can send the detected position information of the measured object 2 in the x-axis direction to the control unit 8.

  The support table 3 is for holding the measurement unit 7 at a position facing the measurement object 2 held by the measurement object support unit 1, and the support table 3 A fixed on the base 20. The support plate 3C that supports the measurement unit 7 and the tilt angle adjustment unit 3B that is provided on the support base 3A and supports the support plate 3C so that the tilt angle with respect to the horizontal plane can be adjusted.

In this embodiment, the tilt angle adjusting unit 3B acts on the measuring unit 7 in the tilt direction by slightly tilting the measuring unit 7 about the x axis so as to face downward from the z-axis positive direction toward the negative direction. It is for generating the force of gravity. Due to the gravitational force due to such a minute inclination, a minute pressing force is generated from the measuring probe 6 described later to the measured object 2.
In the present embodiment, the inclination angle adjusting unit 3B is configured to be spaced apart in the z-axis direction at two locations on the support base 3A, the side closer to the measured object support unit 1 and the side far from the measured object support unit 1, and each in the vertical direction. Angle adjusting members 3a and 3b that advance and retract independently are provided.
In this embodiment, the advance / retreat amount of the angle adjusting members 3a, 3b is adjusted by a motor (not shown) provided at the lower end of the angle adjusting members 3a, 3b and electrically connected to the control unit 8. Yes. The upper ends of the angle adjusting members 3a and 3b are connected to each other on the lower surface of the support plate 3C via a rotary joint or a rotatable support member that constitutes a pin fulcrum.
For this reason, the inclination angle around the x-axis of the support plate 3C can be finely adjusted by the difference in the amount of advancement and retraction of the angle adjustment members 3a and 3b.
Note that the inclination angle adjusting unit 3B may be manually adjusted by providing mechanical means such as screw feeding means for moving the angle adjusting members 3a and 3b back and forth.

The measurement unit 7 is a device part that measures the surface shape of the measurement target 2 held by the measurement target support unit 1, and includes the measurement probe 6, the slider 4 provided on the support plate 3C, and the second position. And a detector 5.
The measurement probe 6 includes a stylus part 6a that abuts on the surface of the measurement object 2 held by the measurement object support part 1, and a rod-shaped body part 6b that supports the stylus part 6a.
The stylus portion 6a is provided in a spherical shape or a wedge shape.

The slider 4 includes a rod-like slider moving portion 4b fixed to the base end portion of the body portion 6b of the measurement probe 6, and a slider support portion 4a that holds the slider moving portion 4b so as to be able to advance and retract along its axial direction. .
The moving direction of the slider moving part 4b is a direction along the z-axis when the support plate 3C is disposed horizontally.
The configuration of the slider 4 is not particularly limited as long as it is a linear motion moving mechanism, and an appropriate linear motion guide can be adopted, but an air slider is employed in the present embodiment. For this reason, the slider support portion 4a is formed with an opening portion penetrating in the horizontal direction, and an air supply portion (not shown) is provided inside the opening portion. Thereby, the slider moving part 4b which penetrates the opening part is floated and supported, and is supported so that it can advance and retreat in the penetration direction of the opening part.
Note that the gap between the air supply unit (not shown) and the slider moving unit 4b is very narrow and has sufficient bearing rigidity against the weight of the slider moving unit 4b to suppress vertical vibration. Has been.
As the material of the slider 4, for example, a metal material such as ceramics or iron, or a glass material can be employed.

The second position detecting unit 5 is for detecting the moving position of the slider moving unit 4b. The second position detection unit 5 is electrically connected to the control unit 8 and can send the detected position information of the slider moving unit 4b in the z-axis direction to the control unit 8.
As a specific example of the second position detection unit 5, for example, a combination of an optical scale and a scale reading sensor, a laser length measuring device, or the like can be employed.

With such a configuration, when the support plate 3C is tilted by the tilt angle adjusting unit 3B, the slider moving unit 4b floatingly supported by the slider support unit 4a moves along the tilt by its own weight. As a result, the measurement probe 6 on the tip side of the slider moving part 4b is pressed against the measurement object 2 held by the measurement object support part 1 with a minute component force, and the stylus part 6a becomes the surface of the measurement object 2 Abut.
In this state, when the drive mechanism 1c is driven and the measurement object 2 moves in the x-axis direction with respect to the measurement probe 6, the stylus portion 6a follows the uneven shape of the surface of the measurement object 2 in the z-axis direction. Will be moved to.
For this reason, the position information of the slider moving unit 4b detected by the second position detecting unit 5 is position information corresponding to the position of the surface shape of the measurement object 2 in the z-axis direction. Further, the position information detected by the first position detection unit 9 is position information corresponding to the position of the stylus part 6 a on the surface of the measurement object 2 in the x-axis direction.

Therefore, by appropriately setting the origins and positive and negative directions of the first position detection unit 9 and the second position detection unit 5, the position information by the second position detection unit 5 is retained by the measured object support unit 1. The measured value of the z coordinate of the surface shape of the measurement object 2 in the xz coordinate system passing through the central axis, and the position information by the first position detector 9 can represent the measured value of the x coordinate.
Therefore, the measurement unit 7, the drive mechanism 1 c, the first position detection unit 9, and the second position detection unit 5 measure the surface shape of the measurement object 2 and generate measurement data of the surface shape. The generation unit is configured. In particular, in the present embodiment, a measurement data generating unit that scans the surface of the measurement object 2 with the measurement probe 6 and generates measurement data of the surface shape based on the movement of the measurement probe 6 is provided.

  The functional configuration of the control unit 8 includes a device control unit 14, a function storage unit 13, a data acquisition unit 10, a data partition unit 11, and an arithmetic processing unit 12, as shown in FIG.

The apparatus control unit 14 controls the entire apparatus of the shape measuring apparatus 50. For example, the drive mechanism 1c and the tilt angle adjusting unit 3B are electrically connected to each other, and a control signal is sent to them to move the drive mechanism 1c and adjust the tilt angle of the tilt angle adjusting unit 3B. It can be done.
For example, an input unit 15 including input means such as a keyboard, a mouse, and an operation button is connected to the device control unit 14, and a drive mechanism is based on information input from a measurer via the input unit 15. The movement amount of 1c and the inclination angle of the inclination angle adjusting unit 3B can be set.
The input unit 15 can also input information on a plurality of functions that define the measurement surface of the measurement object 2.
The function information includes function type information and function domain information. The input method is not particularly limited, but in this embodiment, it is possible to input interactively via an input screen on a monitor (not shown). For example, the function storage unit 13 to be described later has built-in arithmetic programs corresponding to various function forms, and the device control unit 14 acquires information on these built-in functions from the function storage unit 13 and monitors them. Can be displayed. Further, the measurer can appropriately select these functions through the input unit 15 while viewing the display. In addition, parameters such as coefficients included in these functions can be set by inputting numerical values.
The domain of the function can be set by entering numerical values for the upper and lower limits.
Information on these functions input from the input unit 15 is sent to the function storage unit 13.

In addition, when an operation input for starting measurement is made from the input unit 15, the device control unit 14 controls a preset measurement operation.
For example, control for automatically moving the drive mechanism 1c within a measurement range from a preset measurement start position at a constant speed is started, and a control signal is sent to the data acquisition unit 10 to detect the first position. Control for acquiring the position of the device under test 2 and the position of the measurement probe 6 from the unit 9 and the second position detection unit 5 at a constant period is started.
Further, when the preset measurement is finished, these operations are finished, and control for starting the calculation processing of the measurement data acquired by the data acquisition unit 10 is performed.

The function storage unit 13 stores information on a plurality of functions that define the design value of the surface shape, and is communicably connected to the device control unit 14, the data partition unit 11, and the arithmetic processing unit 12.
The function storage unit 13 is provided with a function storage region for storing various functions, and a set value storage region for storing function information input from the input unit 15 and sent from the device control unit 14. .

The data acquisition unit 10 is electrically connected to the first position detection unit 9, the second position detection unit 5, and the device control unit 14, and detects the first position based on a control signal from the device control unit 14. Measurement data is acquired from the unit 9 and the second position detection unit 5.
That is, when a measurement start control signal is received from the apparatus control unit 14, the position information sent from the first position detection unit 9 and the second position detection unit 5 is acquired and stored at a preset sampling cycle. I will do it.
Note that the sampling period is appropriately set so as to include measurement data at a position corresponding to the boundary of each defined area of a plurality of functions, which are design values of the surface to be measured.
When a measurement end control signal is sent from the apparatus control unit 14, the acquired position information is sent to the data partition unit 11 as measurement data composed of a sequence of points in the xz coordinate system.
For example, when N point sequences Q ₀ , Q ₁ ,..., Q _N−1 obtained as measurement data are represented, each measurement data is represented by the following equation (10).

Q _n = (x _n , z _n ) (where n = 0,..., N−1) (10)

The data partition unit 11 partitions the measurement data into subgroups for each of the definition areas of a plurality of functions representing the surface shape of the surface to be measured.
Information on the definition area is stored in a set value storage area of the function storage unit 13. For this reason, the data partition unit 11 can acquire information on the definition area of the function from the set value storage area of the function storage unit 13.
That is, since the data partition unit 11 can acquire the domain D _A , D _B1 , D _B2 , D _C1 , D _C2 of a plurality of functions representing the first surface 2A that is the measured surface, these numerical values are obtained. A subgroup partitioned in accordance with the range is generated, and the measurement data is converted into a plurality of two-dimensional arrays A and B as in the following equations (11), (12a), (12b), (13a), and (13b). ₁ , B ₂ , C ₁ , C ₂ . Hereinafter, these two-dimensional arrays may be referred to as subgroups A, B ₁ , B ₂ , C ₁ , C ₂ .
These two-dimensional arrays are sent to the arithmetic processing unit 12.

Here, K _A , K _B1 , K _B2 , K _C1 , and K _C2 are the numbers of points included in the definition areas D _A , D _B1 , D _B2 , D _C1 , and D _C2 , respectively.
In the following, when the elements of each array are marked, for example, the array subscript is represented as k, and expressed as A (k) = (x _Ak , z _Ak ).

The arithmetic processing unit 12 is communicably connected to the data partition unit 11 and the function storage unit 13, performs arithmetic processing on the measurement data partitioned into the subgroups sent from the data partition unit 11, and finally the measurement data From this, the shape error with respect to the design value of the surface shape is calculated. This arithmetic processing will be described in detail in the operation description to be described later.
The arithmetic processing unit 12 is electrically connected to the output unit 16 and can output the calculated shape error to the output unit 16.
Examples of the output unit 16 include one or more of a monitor that displays the shape error as a numerical value or a graph, a printer that prints the display, and a storage device such as a hard disk that stores the numerical value of the shape error as data. it can.
Further, when the shape error is used for processing, the output unit 16 may be a processing device.

  The device configuration of the control unit 8 is composed of a computer having a CPU, a memory, an input / output interface, an external storage device, and the like, thereby executing a control program and a calculation program corresponding to the control function and calculation function as described above. The control function and calculation function as described above are realized.

Next, the operation of the shape measuring apparatus 50 will be described focusing on the shape measuring method of the present embodiment.
The shape measuring device 50 can measure the shape of the entire first surface 2A including the flange surface 2c, but for the sake of simplicity, the shape measuring device 50 will be described as measuring the shape of only the range of the lens surface 2a and the connecting surface 2b. A supplementary explanation of the case where the flange surface 2c is measured as necessary. Even if it is such description, the shape measurement method in the case of measuring also including the flange surface 2c will be easily understood by those skilled in the art.
FIG. 4 is a flowchart showing a process flow of the shape measuring method according to the first embodiment of the present invention. FIGS. 5A, 5 </ b> B, and 5 </ b> C are schematic graphs illustrating an analysis process and an alignment correction process of the shape measurement method according to the first embodiment of the present invention.

In order to perform shape measurement using the lens surface 2a and the connection surface 2b of the measured object 2 using the shape measuring apparatus 50, steps S1 to S14 are performed according to the flowchart shown in FIG.
In step S1, a shape defining step is performed.
This step is a step of defining the design value of the surface shape of the measurement object 2 by a plurality of functions.
Since the DUT 2 is a lens, the shape of the first surface 2A is already defined by a design formula used for lens design, a mathematical formula that gives lens processing data, or the like. For this reason, the function form and the domain of the shape of the first surface 2A are known, and are expressed as, for example, the above formulas (1), (2a), (2b), (4), and (5). .
Therefore, the measurer interactively inputs the function form and the domain defined as the function information via the input unit 15. The device control unit 14 sends the input function information to the function storage unit 13.
Thus, step S1 is completed.

Next, in step S2, a data acquisition process is performed.
This step is a step of measuring the surface shape of the measurement object 2 and acquiring measurement data of the surface shape.
As shown in FIG. 1, the measurer places the measurement object 2 on the measurement object support 1 so that the reference axis P of the measurement object 2 is horizontally arranged and the first surface 2A faces the measurement unit 7 side. After being held, measurement start is input from the input unit 15.
Upon detecting the measurement start input from the input unit 15, the device control unit 14 drives the drive mechanism 1 c to move the movable body 1 b in the positive x-axis direction, and is the most in the shape measurement range of the measured object 2. The measurement probe 6 is opposed to a point b (see FIG. 3A) that is a position on the x-axis negative direction side.
Next, the device control unit 14 drives the tilt angle adjusting unit 3B to set the tilt angle of the support plate 3C with respect to the horizontal plane to a preset tilt angle. Thereby, the component force of its own weight acts on the slider moving part 4b, and the slider moving part 4b slides in the direction toward the measured object 2. Then, the stylus portion 6a on the distal end side contacts the point b on the first surface 2A.

From this state, the apparatus control unit 14 starts driving the drive mechanism 1c in the negative x-axis direction and sends a measurement signal acquisition start control signal to the data acquisition unit 10.
Thereby, the stylus part 6a moves to the x-axis positive direction side relative to the first surface 2A, and is displaced in the z-axis direction following the unevenness of the first surface 2A.
For this reason, the stylus 6a sequentially passes the points b, c, d, and e shown in FIG. 3A with time, and the point closest to the x-axis negative direction of the first surface 2A in the shape measurement range. f is reached.

While the relative movement is performed and the stylus portion 6a scans the first surface 2A, the first position detection unit 9 detects the position of the measurement object 2 in the x-axis direction, and sequentially The position information is sent to the data acquisition unit 10.
Further, the second position detection unit 5 detects the movement position of the slider movement unit 4b in the x-axis direction, and sequentially sends the position information to the data acquisition unit 10.

The data acquisition unit 10 samples the position information from the first position detection unit 9 and the second position detection unit 5 at a constant sampling period, and acquires it as discrete measurement data.
This measurement data is sent to the data partition unit 11 as a point sequence {Q _n } represented by the above equation (10). Here, the subscript n can be set as appropriate, but in the following, it will be given in the measurement order, and the measurement data having a relatively small subscript becomes the measurement data on the x-axis negative direction side. It shall be.
The coordinates (x _n , z _n ) in the point sequence {Q _n } are based on the xyz coordinate system unique to the shape measuring device 50, and the holding center axis of the measured object support unit 1 is matched with the z axis. ing.
FIG. 5A is a graph showing the relationship between measurement data and design values. In the graph of FIG. 5A, the solid line is a graph of design values represented by z = f (x) and z = g (x), and the broken line schematically shows a point sequence {Q _n }. It is a thing.
In the measurement data, | x | is large outside in the radial direction, and the deviation from the design value is large. In addition to the processing error, the optical axis of the first surface 2A is the holding center axis of the measured object support 1. It includes an error due to being held in a state deviated from. Such an error caused by the displacement of the holding position at the time of measurement or the above-described displacement between the reference axis P of the measured object 2 and the optical axis O is an error relating to the entire measurement data, and the design of the first surface 2A. This is an error different from the shape error for the value. An error that excludes such a shape error and contributes uniformly to the entire measurement data is hereinafter referred to as a misalignment error. In FIG. 5A, for the sake of easy viewing, the positional deviation error is exaggerated and the shape error is hardly shown.
Step S2 is complete | finished above.

  When shape measurement is performed including the flange surface 2c, the shape measurement range is a range from point a to point g.

Next, in step S3, a data partition process is performed.
This step is a step of dividing the measurement data into subgroups for each function domain.
The data partition unit 11 acquires information on the domain of the function defining the first surface 2A stored in the function storage unit 13, and the transmitted point sequence {Q _n } is a subgroup corresponding to each domain. Divide into
Specifically, it is determined in the ascending order of the subscript n whether x _n of the point sequence {Q _n } belongs to the definition area D _A , D _B1 , or D _B2 , and the point (x _n , z _n ) is The two-dimensional arrays A, B ₁ and B ₂ corresponding to the respective domains are sequentially stored. At this time, the boundary points between the adjacent domains are stored in the adjacent domains.
In this way, two-dimensional arrays A, B ₁ and B ₂ as shown in the above formulas (11), (12a), and (12b) are generated as a subgroup of the point sequence {Q _n }, and the arithmetic processing unit 12 is sent out.
This is the end of step S3.

In the case of measuring the shape including the flange surface 2c, in addition to the two-dimensional arrays A, B ₁ and B ₂ as a subgroup of the point sequence {Q _n }, the above formulas (13a) and (13b) Two-dimensional arrays C ₁ and C ₂ shown in FIG.

In the shape measurement method of this embodiment, the shape error is measured by performing alignment correction of the measurement data that minimizes the amount of deviation of the measurement data from the design value. The amount of data movement at the time of alignment correction is a positional deviation error.
At this time, in the present embodiment, after the alignment correction of the first partial group selected from the plurality of partial groups is performed, the second partial group adjacent to the first partial group is corrected to the corrected first partial group. Alignment correction of the measurement data of the second subgroup is performed in a state where the coordinates are converted so that the connection condition at the boundary point with the first subgroup is satisfied, and the coordinates of the second subgroup are adjusted as necessary. By repeating conversion and alignment correction, the entire measurement data is alignment corrected.
In the following steps S4 to S13, an example in which the first partial group is the two-dimensional array A and the second partial group is the two-dimensional arrays B ₁ and B ₂ will be described as an example. Than this, the object to be measured 2 of the present embodiment, the measuring range of the shape of the lens surface 2a is wide, and because larger number of measurement data, for example, a two-dimensional array B ₁ and the first subgroup This is because the accuracy of alignment correction is considered to be good.
However, the selection criterion of the first partial group is not limited to the number of measurement data, but also, for example, select a partial group corresponding to a surface that is estimated to have a small shape error from the surface shape and processing capability. Such selection criteria may be used.

In step S4, the first analysis step is performed on the subgroup A.
This step is a step of estimating a movement parameter that represents the amount of deviation from the design value of the surface shape represented by the two-dimensional array A that is the first partial group.
The positional deviation error of the measurement data can be expressed by shift errors Δx and Δz which are deviation amounts of the parallel movement from the design value and a tilt error θ which is a deviation amount of the rotational movement from the design value. In the present embodiment, shift errors Δx, Δz, and tilt error θ are employed as the movement parameters.

In this step, the arithmetic processing unit 12 performs an operation for estimating the shift errors Δx and Δz and the tilt error θ as the movement parameters of the subgroup A. As an estimation method, the least square method is adopted.
When the subgroup A has shift errors Δx, Δz, and tilt error θ as misalignment errors, a point (x corresponding to when there is no processing error at each point (x _Ak , z _Ak ) of the sub group A _Since the point (x, z) of _A , z _A ) and the design value may be translated and rotated in the direction opposite to the movement parameter, (x _A , z _A ), the following equations (14), (15 ).

These movement parameters are obtained by the least square method calculation process performed by the calculation processing unit 12. That is, the residual sum of squares S (Δx, Δz, θ) represented by the following equation (16) is obtained as the values of Δx, Δz, θ that take the minimum values.
However, (x _i , z _i ) in the following equation (16) is expressed by the following equations (14) and (15) as shown in the following equations (17) and (18), and the two-dimensional array A (i) = This is a value obtained by substituting (x _Ai , z _Ai ) (i = 0,..., K _A −1).

Above, step S4 is complete | finished.
Next, in step S5, a first alignment correction process is performed on the subgroup A.
This step is a step of generating corrected measurement data by performing alignment correction of the measurement data using the movement parameter estimated in the first analysis step.
The arithmetic processing unit 12 substitutes the estimated values obtained in step S4 for Δx, Δz, θ in the above formulas (14) and (15), thereby performing coordinate conversion of each measurement data of the two-dimensional array A. The two-dimensional array A ^* , which is the corrected measurement data of the first subgroup, is generated as in the following equation (19). Hereinafter, the two-dimensional array A ^* may be referred to as a subgroup A ^* after (alignment) correction.

When plotted on the graph, the two-dimensional array A ^* is plotted at a position overlapping the function f (x) except for the processing error of the lens surface 2a, as shown in FIG. 5B.
This is the end of step S5.

In step S6, it performs the data conversion step a subgroup B ₁ adjacent to subgroup A as a target. Steps S6 to S8 are performed j times (j is an integer equal to or greater than 1). First, a case where j = 1 will be described.
In this step, when the boundary in the first subgroup is referred to as the end point and the boundary in the second subgroup is referred to as the start point, the start point coincides with the end point after alignment correction, and the differential coefficient at the start point is the end point after alignment correction. This is a step of performing coordinate conversion of the measurement data of the second subgroup so as to coincide with the differential coefficient at.

As shown in FIG. 5A, when the tilt error is large among the position shift errors, the position shift error around the measurement data increases. For this reason, as shown in FIG. 5B, the deviation of the subgroup B ₁ from the function g (x) that is the design value is larger than the deviation of the subgroup A from the function f (x).
For this reason, if the analysis process and the alignment correction process are performed in the same manner as steps S4 and S5, the correction accuracy of the alignment correction may be deteriorated as compared with the subgroup A.
Further, simply performed only by the alignment correction subgroup B _1, there is a fear that a smooth connection conditions can not be satisfied for correct subgroup after A ^*.
Therefore, in this step, the arithmetic processing section 12, that it is subgroup ^{A *} of the end point of the corrected ^{_{A * (K A -1) =}} (x A * (KA-1), z A * (KA-1 ₎₎ and, that it is the starting point of the subgroup _{B 1 B 1 (0) =} (x B10, z B10) difference between by taking a point _B 1 (0) * a point ^a _(K a -1) The parallel movement amounts Δx ₁ and Δz ₁ to be matched with each other are calculated.
In addition, the arithmetic processing unit 12 calculates the differential coefficient z _A ^* ′ (x _A ^* _(KA−1) ) at the end point of the corrected subgroup A ^* and the differential coefficient z _B1 ′ at the start point of the subgroup B ₁ ( 0), a rotational movement amount θ ₁ for smoothly connecting the start point of the subgroup B ₁ to the end point of the subgroup A ^* is calculated. The differential coefficient is calculated by numerical calculation of measurement data.
As a result, a transformation matrix H ₁ represented by the following equation (20) (where j = 1) is generated.

Next, the arithmetic processing unit 12 performs data conversion on each point of the two-dimensional array B ₁ by the following equation (21). However, the right side of Expression (21) uses the following Expressions (22) and (23) when j = 1.

In this way, a two-dimensional array B ₁ ^{* (1)} whose coordinates are converted so that the start point is smoothly connected to the end point of the first subgroup is generated. Hereinafter, the two-dimensional array B ₁ ^{* (1)} may be referred to as a subgroup B ₁ ^{* (1)} after coordinate transformation.
This is the end of step S6.

Next, in step S7, a second analysis step is performed on the subgroup B ₁ ^{* (1)} .
This step is a step of estimating a movement parameter representing an amount of deviation from the design value of the surface shape by the two-dimensional array B ₁ ^{* (1)} that is the second partial group.
In this step, only the target subgroups are different, and the shift error Δx, Δz, tilt error θ, which are the movement parameters of the two-dimensional array B ₁ ^{* (1),} are performed by the arithmetic processing unit 12 in the same manner as in step S4. Perform an operation to estimate. That is, Δx, Δz, θ is obtained from the following formulas (24), (25), (26) by the least square method. These estimated values of Δx, Δz, θ are generally different from the estimated values in step S4.

以上でステップＳ７が終了する。

Step S7 is complete | finished above.

Next, in step S8, a second alignment correction process is performed on the subgroup B ₁ ^{* (1)} .
This step is a step of generating corrected measurement data by performing alignment correction of the measurement data using the movement parameter estimated in the second analysis step.
This step is substantially the same as step S5 described above except that the target subgroup is different. The arithmetic processing unit 12 substitutes the estimated values obtained in step S7 for Δx, Δz, θ in the coordinate transformation equations shown in the above equations (25), (26), and thereby the two-dimensional array B ₁ ^{* (1 )} Is transformed to generate a two-dimensional array B ₁ ^* which is the corrected measurement data of the second subgroup as shown in the following equation (27). Hereinafter, the two-dimensional array B ₁ ^* may be referred to as a subgroup B ₁ ^* after (alignment) correction.

In this way, as shown in FIG. 5C, the subgroup B ₁ is corrected for alignment as the subgroup B ₁ ^* .
Above, step S8 is complete | finished.

Next, in step S9, a convergence determination step is performed.
This step calculates a slope deviation due to a difference between the differential coefficient at the end point of the first partial group corrected in step S5 and the differential coefficient at the start point of the second partial group corrected in step S8. In this step, it is determined whether the inclination deviation is equal to or less than a preset allowable value.

In step S6, the end point of the connected subgroup A ^{* and} the start point of the subgroup B ₁ ^{* (1)} are connected. In steps S7 and S8, the measurement data of the subgroup B ₁ ^{* (1)} is connected. Since alignment correction is performed using the whole, the start point of the corrected subgroup B ₁ ^* may be slightly shifted from the end point of the subgroup A ^* .
Therefore, in this step, the differential coefficient z _A ^* ′ (x _{A (KA−1)} ^* ) at the end point of the corrected subgroup A ^* and the differential coefficient z _B1 ^* ′ (at the start point of the subgroup B ₁ ^* Taking the difference from x _B10 ^* ), the inclination deviation Δθ shown in the following equation (28) is calculated.
Further, a positional deviation ΔL between the corrected end point of the subgroup A ^* and the start point of the subgroup B ₁ ^* is calculated as in the following equation (29).

The arithmetic processing unit 12 determines whether the magnitudes of Δθ and ΔL are equal to or less than allowable values. The allowable value can be appropriately set as necessary, but in the present embodiment, as an example, a value less than the minimum value ε of the numerical value range of the computer used for the control unit 8 is set as the allowable value. Therefore, when the calculation results of the magnitudes of the inclination deviation Δθ and the position deviation ΔL cause an underflow error, or when they coincide with 0, it is determined that the calculated value is equal to or less than the allowable value.
If any of the inclination deviation Δθ and the position deviation ΔL is larger than the allowable value, the process proceeds to step S6, and the above steps S6 to S8 are repeated. The operation of each of these steps is the same as that described above except that the value of j is replaced with the value of the number of repetitions.
When the magnitudes of the inclination deviation Δθ and the position deviation ΔL are equal to or smaller than the allowable values, the process proceeds to step S10.

Steps S10 to S13 are steps for performing a loop process substantially similar to steps S6 to S9 described above.
That is, step S10 is data conversion step of a two-dimensional array (subgroup) _{B 2} and the object as the second subgroup, two-dimensional array ^{_{(subgroup) B 2 * (j) (}} j is 1 or more Integer).
Step S11 is a second analysis step for the subgroup B ₂ ^{* (j)} , and Δx, Δz, and θ are obtained. However, as shown in FIG. 5A, the end point of the first subgroup is A (0), and the start point of the _second subgroup is B ₂ (K _B2 −1).
Step S12 is a second alignment analysis step for the subgroup B ₂ ^{* (j)} , and a two-dimensional array (subgroup) B ₂ ^* is obtained.
Step S13 is a convergence determination step, and the inclination deviation Δθ is calculated. If the inclination deviation Δθ is larger than the allowable value, the process proceeds to step S10 and the above steps S10 to S12 are repeated. If the slope deviation Δθ is equal to or less than the allowable value, the process proceeds to step S14.
For the details of steps S10 to S14, “B ₁ ” may be read as “B ₂ ” in the description and formulas of steps S6 to S9.

When shape measurement is performed including the flange surface 2c, the subgroup B ₁ ^* (B ₂ ^* ) is the first subgroup, and the two-dimensional array C ₁ (C ₂ ) is the second subgroup. A loop process substantially similar to steps S6 to S9 is performed.

In step S14, a shape error calculation step is performed.
This step is a step of calculating a deviation between the corrected measurement data and the plurality of functions as a shape error.
The arithmetic processing unit 12 obtains an alignment-corrected point sequence {Q _n ^* } from the two-dimensional arrays A ^* , B ₁ ^* , B ₂ ^* , which are corrected measurement data calculated up to step S13, by the following equation (30 ). Here, since the coordinate values of the boundary points of each subgroup coincide in the alignment correction process, the point sequence is selected so as not to overlap. For this reason, the number N of points does not change.

Q _n ^* = (x _n ^* , z _n ^* ) (where n = 0,..., N−1) (30)

Next, the arithmetic processing unit 12 determines which of the definition areas x _n ^* belongs to, calculates the shape error E _z (n) by the following equation (31), and outputs it to the output unit 16.

E _z (n) = z _n ^* −F (x _n ^* ) (31)

Here, the function F means a function that varies depending on the domain to which x _n ^* belongs. For example, the function F in the domain D _{A and} the function g in the domains D _B1 and D _B2. . For this reason, it calculates using Formula (1), (2a), (2b), respectively.
Thus, step S14 is completed and the shape measuring method of the present embodiment is completed.

  As described above, the arithmetic processing unit 12 estimates the movement parameter indicating the movement amount when the surface shape by the subgroup is obtained by movement from the corresponding function, and the analysis unit estimates An alignment correction unit for performing alignment correction of the measurement data using the transferred parameters and generating corrected measurement data; and a shape error calculation unit for calculating a deviation between the corrected measurement data and a plurality of functions as a shape error; Is configured.

As described above, according to the shape measuring apparatus 50 and the shape measuring method using the same, the measurement data is divided into subgroups for each domain of the plurality of functions, and the deviation from the design value of the surface shape by each subgroup. Since the movement parameter representing the quantity can be estimated and the alignment correction of the measurement data can be performed, the alignment correction of the measurement data can be performed even when the design value of the surface shape of the measured object 2 is defined by a plurality of functions. It can be measured as the amount of deviation from the design value of the surface shape of the object to be measured.
For this reason, it is possible to accurately measure a shape error with respect to a design value even for a measurement object having a complicated shape.
Further, since a plurality of functions can be stored in the function storage unit 13, even a shape unique to the measured object different from a commonly used surface shape such as a lens surface is given as a function. If it is a shape, a shape error can be measured accurately.

For example, in measuring the shape of an optical element such as a lens, the surface shape of the lens effective area is important, but the stylus portion 6a has a finite size. For this reason, it is preferable to measure by moving the stylus part 6a slightly outside the necessary lens effective area in order to reliably cover the necessary lens effective area.
However, in recent years, the surface shape of the lens surface is formed only in a range very close to the necessary lens effective area in order to reduce the size of the lens and improve the processing cost. For this reason, there is a possibility that a surface shape different from the shape of the lens surface is being measured in the vicinity of the lens effective area. If alignment correction is performed in consideration of such measurement points, the accuracy of alignment correction deteriorates. There is a risk.
In the present embodiment, in addition to the surface shape of the lens surface 2a constituting the lens effective region, the design value of the surface shape of the connection surface 2b outside the lens effective region adjacent to the lens surface 2a is given as a function g. . Therefore, even if the stylus part 6a is not accurately brought into contact with the boundary position between the lens surface 2a and the connection surface 2b, the alignment correction is performed by using a plurality of measurement data that definitely belong to the domain of the function g. Since the calculation is performed by the included calculation, the accuracy of alignment correction can be improved.

Next, a processing method using the shape measuring method of this embodiment will be described.
FIG. 6 is a schematic plan view showing a schematic configuration of a processing apparatus used in the processing method according to the first embodiment of the present invention. FIGS. 7A and 7B are schematic graphs showing examples of shape error data obtained by the shape measurement method according to the first embodiment of the present invention, and how to obtain machining data. This is a schematic graph.

The processing method of the present embodiment processes a workpiece in which the surface shape of the processing target is defined by a plurality of functions, and uses the workpiece as a measurement object, by the shape measurement method of the present embodiment, the workpiece This is a method of measuring a shape error with respect to a surface shape of a processing target of an object, and reworking the workpiece so as to correct the shape error when the shape error exceeds a preset allowable value.
This processing method can be performed by, for example, a processing apparatus 60 shown in FIG.
The processing device 60 performs processing such as cutting processing, grinding processing, polishing processing, etc. on a workpiece 64 whose processing target surface shape is represented by the same function as that of the measured object 2, and before and after the processing. This is an apparatus capable of on-machine measurement of the surface shape without releasing the holding of the workpiece 64.
The processing device 60 includes a workpiece holding base 61 and an NC control unit 63 instead of the measured object support unit 1 and the output unit 16 of the shape measuring device 50, and includes a processing unit 62.
Hereinafter, a description will be given focusing on differences from the shape measuring apparatus 50 described above.

The workpiece holding table 61 includes a spindle 61b that holds the holding table 1a so as to be rotatable about the Z axis, instead of the movable body 1b of the measured object support unit 1.
The spindle 61b stops rotating during shape measurement, and can hold the workpiece 64 in a fixed positional relationship with respect to the measurement unit 7.

The NC control unit 63 controls the operation of the drive mechanism 1c and the operation of the processing unit 62 based on a plurality of functions representing the surface shape of the workpiece 64 set in advance at the time of processing. It controls surface processing and is electrically connected to the drive mechanism 1 c, the first position detection unit 9, and the processing unit 62.
The NC control unit 63 is electrically connected to the control unit 8 and stores a plurality of functions in the function storage unit 13 of the control unit 8 or acquires shape error data output from the control unit 8. Can be done.

The processing unit 62 includes a tool 62a for processing the workpiece 64, a drive shaft 62b for rotationally driving the tool 62a, and a drive shaft 62b for moving the tip tool 62a on a predetermined movement locus based on a plurality of functions. And a drive shaft moving part 62c to be moved.
The processing unit 62 and the measuring unit 7 are provided in a positional relationship that does not interfere with each other during processing and shape measurement. Each arrangement position may be provided such that at least one of the processing unit 62 and the measurement unit 7 is movable as long as the positional relationship at the time of processing and shape measurement corresponds to one to one. Further, by fixing the positions of the processing unit 62 and the measurement unit 7 on the base 20 and driving the drive mechanism 1c, the arrangement position of the workpiece 64 is switched between when processing and when measuring the shape. Also good.

According to such a processing apparatus 60, the workpiece 64 can be held on the holding table 1a, positioned in the processing region of the processing unit 62 by the drive mechanism 1c, and the surface shape can be processed by the processing unit 62. . At this time, the operation control of the processing unit 62 is performed by the NC control unit 63.
The NC control unit 63 generates NC machining data based on the machining target surface shape, and controls the operation of the drive shaft moving unit 62c and the drive mechanism 1c.

When the processing is completed, the workpiece 64 is positioned in the shape measurement region of the measuring unit 7, and the shape measurement can be performed in the same manner as the shape measuring device 50.
At this time, functions f, g, and the like representing design values of the first surface 2A, which is the surface to be measured of the workpiece 64, can be input from the input unit 15 in the same manner as described above. A plurality of functions stored in the control unit 63 are sent to the function storage unit 13 by the NC control unit 63.

The measurement unit 7 measures the shape of the first surface 2A in the same manner as described above. Thereby, the shape error E _z is calculated. Although the shape error E _z is a point sequence, since the distance between the points is extremely small, it can be schematically plotted as curves 101 and 102 shown in FIG.
The shape error E _z is displayed on a monitor (not shown) as needed and sent to the NC control unit 63.

In shape error E _z NC control unit 63 has received, it analyzes the shape error E _z, if the shape error E _z exceeds a preset allowable value, creates the NC machining data for reprocessing, the NC Rework based on the data. In this way, the processing and the shape measurement are repeated, and the processing is continued until a shape error less than the allowable value is obtained. Thereby, the process of the workpiece 64 is complete | finished.

The NC machining data for reworking can be configured, for example, to rework the entire surface by moving the movement amount of the tool 62a in the direction opposite to the shape error _Ez . Also, of the shape error E _z, it can be reprocessed only the part that is a convex shape (z> 0 part of) relative to the surface shape function is represented.

Further, when the workpiece 64 has a rotationally symmetric surface shape as in the present embodiment, it is often performed along one radius. In this case, it is meaningless to distinguish between the shape error E _z (see curve 101) of x ≧ 0 and the shape error E _z (see curve 102) of x <0 in FIG. For example, as shown in FIG. 7B, an average value of a curve 103 that is folded around the curve 101 and the curve 102 is obtained as a curve 104, and NC machining data may be generated based on the curve 104.

Thus, according to the processing apparatus 60, the shape error based on the shape measuring method of this embodiment can be fed back at the time of reworking.
At that time, since the processing and the shape measurement can be performed without removing the workpiece 64 from the holding table 1a, the measured shape error can be reflected in the processing with higher accuracy. Further, when switching between processing and measurement, the work 64 is not required to be attached / detached or aligned, so that productivity is improved.

[Second Embodiment]
Next, a shape measuring method according to the second embodiment of the present invention will be described.
FIG. 8 is a flowchart showing a process flow of the shape measuring method according to the second embodiment of the present invention.

The shape measuring method of the present embodiment is a method in which the data conversion process in the first embodiment is deleted, and the analysis process and the alignment process performed for each subgroup are performed collectively.
Hereinafter, as in the first embodiment, an example in which the shape measurement device 50 is used to measure the shape of the lens surface 2a and the connection surface 2b of the measurement object 2 will be described. Further, the description will be focused on differences from the first embodiment.

The shape measuring method of this embodiment is a method of performing steps S20 to S25 based on the process flow shown in FIG.
Steps S20 to S22 are the same processes as steps S1 to S3 of the first embodiment, and constitute a shape definition process, a data acquisition process, and a data partition process, respectively.

Next, in step S23, an analysis process substantially similar to step S4 of the first embodiment is performed on the subgroups A, B ₁ and B ₂ .
This step is a step of estimating a movement parameter representing the amount of deviation from the design value of each surface shape represented by the subgroups A, B ₁ and B ₂ . However, it differs from the first embodiment in that the design values of the respective subgroups are represented by different functions f and g, and the movement parameter is estimated as a value common to all the subgroups.

  In the present embodiment, shift errors Δx, Δz and tilt error θ, which are movement parameters, are common to each subgroup. These estimated values are obtained by the arithmetic processing unit 12 through arithmetic processing of the least square method. That is, the residual sum of squares S (Δx, Δz, θ) represented by the following equation (32) is obtained as the values of Δx, Δz, θ that take the minimum values.

However, (x _i , z _i ) in the equation (32) is different for each of the three summation symbols, and in the first term, the following equations (35) and (36) are used, and in the second term, the above equations (17) and ( 18) In the third term, the following equations (33) and (34) are used.

  Thus, step S23 is completed.

Next, in step S24, an alignment correction process substantially similar to step S5 of the first embodiment is performed on the subgroups A, B ₁ and B ₂ .
This step is a step of generating corrected measurement data by performing alignment correction of measurement data using the movement parameter estimated in the analysis step.
The arithmetic processing unit 12 assigns the estimated values obtained in step S4 to Δx, Δz, θ of the coordinate transformation formula shown in the following formula (37), thereby each of the two-dimensional arrays A, B ₁ , B ₂ Coordinate conversion is performed by substituting the measurement data into x _n and z _n to generate a two-dimensional array Q _n ^* = (x _n ^* , z _n ^* ), which is the corrected measurement data of each subgroup.
However, at the time of coordinate conversion, the measurement data at the boundary points of each subgroup, for example, B ₂ (K _B2 −1) and A (0) are the same measurement data, so that they are not duplicated. For this reason, the number N of points does not change.

Above, step S24 is complete | finished.
Next, in step S25, a shape error calculation step substantially similar to step S14 of the first embodiment is performed.
In this embodiment, since the corrected measurement data Q _n ^* is calculated in step S24, the same operation as that after the calculation of Q _n ^{* in} step S14 is performed in this step.
Thereby, the shape error E _z (n) is calculated by the above equation (31) and output to the output unit 16.
Thus, step S25 is completed and the shape measuring method of the present embodiment is completed.
To do.

In the shape measurement method of this embodiment, as in the first embodiment, the measurement data is divided into subgroups for each domain of a plurality of functions, and the deviation amount from the design value of the surface shape by each subgroup. Therefore, even when the design value of the surface shape of the measurement object 2 is defined by a plurality of functions, the alignment correction of the measurement data is performed. In addition, it can be measured as the amount of deviation from the design value of the surface shape of the object to be measured.
Moreover, it can use suitably for the processing method similar to 1st Embodiment.
The difference from the first embodiment is that alignment correction is performed on each partial group using a common movement parameter. For this reason, a process is simplified more compared with 1st Embodiment.

In the above description, the measurement data generation unit has been described as an example in which contact measurement is performed by scanning the measurement probe 6 on the measurement target surface of the measurement target 2. However, this is an example, and the shape measurement is performed. Other measuring means may be employed. For example, non-contact measurement using a laser displacement meter or the like may be employed.
Further, the scanning of the measurement probe 6 in the x-axis direction has been described in the example of the case where the measurement object 2 is moved, but the measurement probe 6 may be moved in the x-axis direction for measurement.

  In the above description, the example of measuring the surface shape along the cross section of the object to be measured has been described. However, if the design value of the surface shape is given by a plurality of functions, it can be applied to a three-dimensional surface shape. May be.

  Further, in the above description, since the lens surface 2a is a rotationally symmetric spherical surface or aspherical surface, the function representing the surface shape is described as an example in the case of an axisymmetric aspherical expression. However, the object to be measured may have a rotationally asymmetric surface shape. In this case, an axially asymmetric function can be adopted as the function representing the surface shape.

In the description of the first embodiment, the first partial group is the partial group A and the second partial group B ₁ , B ₂ with respect to the three partial groups A, B ₁ , B ₂ . However, this setting is only an example.
For example, the alignment correction is performed with the first partial group as the partial group B ₁ , the second partial group as the partial group A, and the partial group A ^* after the alignment correction is set as the first partial group. it is also possible to alignment correction as subgroup B _2.

  Further, in the above description, when the surface shape is a lens surface, the example in which the range of the lens effective diameter is defined by one function has been described. However, the definition area of a plurality of functions should be set arbitrarily. Therefore, the lens effective diameter may be divided into a plurality of definition areas, and the surface shape of each definition area may be defined by different functions.

  In the above description of the first embodiment, the convergence determination step is provided and the steps S6 to S8 and the like are repeated. However, predetermined measurement accuracy is obtained depending on the measurement conditions and the like. If the number of repetitions necessary for this is known in advance, or if it is known in advance that a predetermined measurement accuracy that does not require repeating each step such as steps S6 to S8 is obtained, the convergence determination step is omitted. May be.

In the above description of the first embodiment, the convergence condition is that the slope deviation Δθ and the position deviation ΔL are equal to or less than the allowable values in the convergence determination step, and the allowable values are less than the minimum value ε of the numerical value range of the computer. As the value of, the coordinate values of the boundary points of each subgroup substantially coincide with each other.
However, the degree of coincidence of the boundary points can be set as appropriate depending on the required measurement accuracy and processing accuracy.
In addition, it is not essential to include the position deviation ΔL in the convergence condition in the convergence determination step.
For example, after matching the boundary points in the data conversion process, the second alignment correction process fixes the boundary points and performs alignment correction calculation (alignment correction with constraints) only in the rotation direction. For example, the same alignment correction can be performed even if only the inclination deviation Δθ is used for the determination of the convergence condition.

  In the above description, the example in which the design value of the surface shape is expressed by a plurality of smoothly connected functions has been described. For example, the differential coefficient is discontinuous at the boundary point of the function such as a corner. It may be. In this case, alignment correction may be performed so that the difference between the differential coefficients at the boundary points becomes a predetermined difference.

  In the above description, an example in which the processing apparatus can perform on-machine measurement has been described. However, the measurement unit 7 is deleted and shape measurement is performed by another apparatus such as the shape measurement apparatus 50. It may be.

  Moreover, all the components described in the above embodiments can be implemented by appropriately changing or deleting the combination within the scope of the technical idea of the present invention.

1 to-be-measured object support part 1a holding stand 1c drive mechanism (measurement data generation part)
2 Object to be measured (workpiece)
2A 1st surface (surface shape)
2a Lens surface 2b Connection surface 2c Flange surface 5 Second position detection unit (measurement data generation unit)
7 Measurement unit (measurement data generation unit)
8 Control unit 9 First position detector (measurement data generator)
10 data acquisition unit 11 data partition unit 12 arithmetic processing unit (analysis unit, alignment correction unit, shape error calculation unit)
13 function storage unit 50 shape measuring device A ^* , B ₁ ^* , B ₂ ^* two-dimensional array (corrected measurement data)
D _A , D _B1 , D _B2 , D _C1 , D _C2 Domains f, g, h Function O Optical axis P Reference axis Q _n Point sequence (measurement data)
z Surface shape

Claims (7)

A shape measuring method for measuring the surface shape of a measured object,
A shape defining step for defining a design value of the surface shape by a plurality of functions;
A data acquisition step of measuring the surface shape and acquiring measurement data of the surface shape;
A data partitioning step of partitioning the measurement data into subgroups for each domain of the function;
An analysis step for estimating a movement parameter representing an amount of deviation from the design value of the surface shape for each of the subgroups;
An alignment correction step of performing an alignment correction of the measurement data using the movement parameter estimated in the analysis step to generate corrected measurement data;
A shape error calculating step of calculating a deviation between the corrected measurement data and the plurality of functions as a shape error;
A shape measuring method comprising: Two partial groups that are adjacent to each other and connected at the boundary among the partial groups are referred to as a first partial group and a second partial group, the boundary in the first partial group is an end point, and the second partial group The boundary in step 1 is referred to as a starting point, and the analysis step and the alignment correction step performed on the first and second subgroups are respectively referred to as a first analysis step and a first alignment correction step. When calling
After performing the first analysis step and the first alignment correction step in this order,
The coordinate conversion of the measurement data of the second subgroup is performed so that the start point coincides with the end point after alignment correction, and the differential coefficient at the start point coincides with the differential coefficient at the end point after alignment correction. Perform the data conversion process,
Performing the second analysis step and the second alignment correction step in this order on the measurement data of the second partial group after the coordinate conversion in the data conversion step,
The shape measurement method according to claim 1, wherein the shape error calculation step is performed after the second alignment correction step. Between the second alignment correction step and the shape error calculation step, an inclination deviation due to a difference between the differential coefficient at the end point subjected to alignment correction and the differential coefficient at the start point subjected to alignment correction is calculated, and the inclination is calculated. A convergence determination step of determining whether the deviation is equal to or less than a preset allowable value,
In the convergence determination step, when the inclination deviation is less than or equal to an allowable value, the shape error calculation step is performed,
When the inclination deviation exceeds an allowable value, based on the measurement data in the convergence determination step, the data conversion step, the second analysis step, the second alignment correction step, and the convergence determination step The shape measuring method according to claim 2, wherein the steps are repeated in this order. A shape measuring method for measuring the surface shape of a measured object,
A shape defining step for defining a design value of the surface shape by a plurality of functions;
A data acquisition step of measuring the surface shape and acquiring measurement data of the surface shape;
A data partitioning step of partitioning the measurement data into subgroups for each domain of the function;
Deviation from the design value of the surface shape by performing a least squares calculation that minimizes the residual sum of squares using the function for each subgroup and the residual sum of squares using the measurement data An analysis step for estimating a movement parameter representing as a value common to all of the subgroups ;
An alignment correction step of performing an alignment correction of the measurement data using the movement parameter estimated in the analysis step to generate corrected measurement data;
A shape error calculating step of calculating a deviation between the corrected measurement data and the plurality of functions as a shape error;
A shape measuring method comprising: Machining a workpiece whose surface shape is defined by multiple functions,
By measuring the shape error of the workpiece with respect to the surface shape of the processing target by the shape measuring method according to any one of claims 1 to 4 , wherein the workpiece is the measurement object,
A processing method comprising: reworking the workpiece so as to correct the shape error when the shape error exceeds a preset allowable value. A shape measuring device for measuring the surface shape of a measured object,
A function storage unit that stores information of a plurality of functions that define design values of the surface shape;
A measurement data generating unit that measures the surface shape of the object to be measured and generates measurement data of the surface shape;
A data acquisition unit for acquiring the measurement data;
A data partition section that partitions the measurement data into subgroups for each domain of the function;
An analysis unit that estimates a movement parameter representing a movement amount when the surface shape is obtained by movement from the corresponding function for each of the subgroups;
An alignment correction unit that performs alignment correction of the measurement data using the movement parameter estimated by the analysis unit and generates corrected measurement data;
A shape error calculation unit for calculating a deviation between the corrected measurement data and the plurality of functions as a shape error;
A shape measuring apparatus comprising: A shape measuring device for measuring the surface shape of a measured object,
A function storage unit that stores information of a plurality of functions that define design values of the surface shape;
A measurement data generating unit that measures the surface shape of the object to be measured and generates measurement data of the surface shape;
A data acquisition unit for acquiring the measurement data;
A data partition section that partitions the measurement data into subgroups for each domain of the function;
By performing a least squares calculation that minimizes the residual sum of squares using the function for each subgroup and the residual sum of squares using the measurement data, the surface shape is derived from the corresponding function. An analysis unit for estimating a movement parameter representing a movement amount when obtained by movement as a value common to all of the subgroups;
An alignment correction unit that performs alignment correction of the measurement data using the movement parameter estimated by the analysis unit and generates corrected measurement data;
A shape error calculation unit for calculating a deviation between the corrected measurement data and the plurality of functions as a shape error;
A shape measuring apparatus comprising:

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