KR101845379B1 - Processed facilities of diffractive optical element pattern and Processed method of diffractive optical element pattern - Google Patents

Abstract

A DOE pattern processing apparatus according to the present invention includes: a numerical value input device for receiving an information value of an aspherical shape and a DOE pattern for processing the lens surface; An aspherical surface path generating device for generating an aspheric path for processing the lens surface into a symmetrical aspherical surface shape corresponding to the information value input by the numerical value inputting device; An aspheric surface machining device for machining the lens surface to a symmetric aspheric surface along an aspherical surface path generated by the aspheric surface path generating device; A DOE pattern path generating device for generating a DOE pattern path for processing the groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining device in correspondence with the information value inputted by the numerical value inputting device; And a DOE pattern processing apparatus for processing the groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path generated by the DOE pattern path generating apparatus.
According to the DOE pattern processing apparatus and method for processing the DOE pattern according to the present invention, by forming the aspherical path and the DOE pattern path according to the size of the lens and the constant value of the formula received through the numerical input device and the numerical input step, The shape of the DOE pattern can be processed on the surface of the asymmetric aspherical surface, and the processing efficiency is high.

Description

[0001] The present invention relates to a diffractive optical element

The present invention relates to a DOE pattern processing apparatus and a processing method thereof, and more particularly, to a DOE pattern processing apparatus for processing a lens surface into a symmetrical aspherical shape and processing a DOE pattern on a surface of a symmetric aspherical surface, .

Generally, the refraction angle of light becomes smaller as the wavelength becomes longer, and becomes larger as the wavelength becomes shorter. Due to the difference in refractive angle according to the wavelength, chromatic aberration occurs in the light transmitted through the lens. In order to reduce the chromatic aberration of the lens, a diffractive optical element (DOE) pattern is formed on the surface of the lens by the above-described light characteristics. By forming the surface of the lens in the DOE pattern, the light is diffracted and irradiated to a predetermined area without being spread widely, so that a uniform light efficiency can be obtained in a necessary area.

Korean Patent No. 10-0706716 discloses a technique related to conventional DOE pattern processing.

However, in the conventional DOE pattern processing, the lens surface is processed into a DOE pattern at one time using a tool formed by protruding a DOE pattern. Therefore, a tool corresponding to the size and shape of the lens must be manufactured in accordance with the size and shape of the lens, respectively. Therefore, there is a problem in that the processing efficiency is lowered when the DOE pattern is processed in lenses of different sizes.

On the other hand, the lens surface forms a circular pattern with the rotation axis at the center of the lens, and the light coming from the peripheral portion generates spherical aberration by refraction. The spherical aberration causes the image of the peripheral portion to be blurred, causing color dispersion and distortion. In order to compensate for the disadvantages of such a circular pattern, it is possible to form a clear image by forming an aspherical surface on one or more surfaces in order to achieve a necessary aberration correction state with a small number of surfaces. Therefore, before the DOE pattern is processed on the lens surface, it is required to perform aspheric surface processing in which the lens surface is formed into a symmetrical aspherical shape.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-described problems, and it is an object of the present invention to process a lens surface in a shape of a symmetrical aspherical surface corresponding to the size and shape of a lens and to process a DOE pattern on a surface of a machined symmetric aspherical surface And to provide a DOE pattern processing apparatus and a processing method thereof that improve the efficiency of processing.

According to an aspect of the present invention, there is provided a DOE pattern processing apparatus for processing a symmetric aspheric surface and a DOE pattern on a lens surface, the apparatus comprising: an aspherical surface shape for processing the lens surface; A numerical value input device for inputting an information value of the information; An aspherical surface path generating device for generating an aspheric path for processing the lens surface into a symmetrical aspherical surface shape corresponding to the information value input by the numerical value inputting device; An aspheric surface machining device for machining the lens surface to a symmetric aspheric surface along an aspherical surface path generated by the aspheric surface path generating device; A DOE pattern path generating device for generating a DOE pattern path for processing the groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining device in correspondence with the information value inputted by the numerical value inputting device; And a DOE pattern processing apparatus for processing the groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path generated by the DOE pattern path generating apparatus.

Here, the numerical value input device may receive design values for an aspherical shape, values for aspheric shapes, shapes of tools for processing DOE patterns, and data for the DOE patterns.

The aspheric path generating apparatus may further include an aspherical path generating unit for generating an aspheric path corresponding to the information value input from the numerical value inputting apparatus, And an aspherical surface path determination unit for determining whether or not the aspherical surface path generation unit has matched the aspherical surface path generation unit and the aspheric surface path generation unit, And an abrasive code generation unit. Also, in the aspherical surface path determination unit, when it is determined that the aspheric surface path generated from the aspheric surface path generation unit and the predetermined aspherical surface finish position are inconsistent, it is preferable that the aspherical surface path generation unit recreates the aspherical surface path.

The DOE pattern path generating apparatus further includes a DOE pattern generating unit for generating a DOE pattern path for forming a DOE pattern groove on the surface of the asymmetric aspheric surface processed by the aspheric machining apparatus, A DOE pattern path determination unit for determining whether or not the DOE pattern path generated by the DOE pattern path generation unit matches a preset DOE pattern processing end position; And a DOE pattern machining code generating section for generating a DOE pattern machining code when it is determined that the DOE pattern path generated from the pattern path generating section matches the predetermined DOE pattern machining end position. When the DOE pattern path determination unit determines that the DOE pattern path generated by the DOE pattern path generation unit and the predetermined DOE pattern processing end position do not match, the DOE pattern path generation unit regenerates the DOE pattern path .

The DOE pattern path generation unit may further include start point calculation means for calculating a start point of a DOE pattern for machining on a surface processed to a symmetric aspherical surface and a calculation unit for calculating a depth point of the DOE pattern based on the start point calculated by the start point calculation means Depth point calculation means for calculating a depth point of the DOE pattern based on the depth point calculated by the depth point calculation means and an end point calculation means for calculating an end point of the DOE pattern based on the width calculated from the width calculation means And an end point calculation means.

It is also preferable that the starting point calculating means calculates the starting point Pt1 of the DOE pattern using the following equations (5) and (6).

&Quot; (5) "

&Quot; (6) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, W _i is the width of the ith DOE pattern, and Dm is the radius of the DOE pattern tool.

It is also preferable that the depth point calculating means and the width calculating means calculate the depth point Pt2 and the width Pt3 of the DOE pattern by using the following expression (7).

&Quot; (7) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, And d _i represents the depth of processing of the ith DOE pattern.

It is preferable that the end point calculation means calculates the end point Pt4 of the DOE pattern by using the following equations (8) and (9).

&Quot; (8) "

&Quot; (9) "

Where R, k, and A _j are constants determined by the shape of the lens as a design parameter, R is the radius of curvature, k is the conic constant, A _j is the Ashperic Coefficients, X _i is the lens radial position of the ith DOE pattern , Dm is the radius of the DOE pattern tool, and W _i is the width of the ith DOE pattern.

On the other hand, in the DOE pattern processing method according to the present invention for processing a symmetric aspheric surface and a DOE pattern on a lens surface, an information value of an aspheric surface shape for processing the lens surface and a DOE pattern is input A numerical input step; An aspherical surface path generation step of generating an aspheric surface path for processing the lens surface into a symmetric aspherical surface shape corresponding to the information value input in the numerical value input step; An aspherical surface machining step of machining the lens surface to a symmetric aspheric surface along the aspherical surface path generated in the aspherical surface path generating step; A DOE pattern path generating step of generating a DOE pattern path for processing a groove of the DOE pattern on the surface of the symmetric aspherical surface in correspondence with the information value inputted in the numerical value input step; And a DOE pattern processing step of processing a groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path generated in the DOE pattern path generating step.

Here, it is preferable that the numerical value inputting step inputs the design value for the aspherical shape, the value for the aspheric shape, the shape of the tool for processing the DOE pattern, and the data for the DOE pattern.

The aspherical surface path generation step may include an aspheric surface path step of generating an aspherical surface path corresponding to the information value input in the numerical value input step, and a step of determining whether or not the aspheric surface path generated in the aspheric surface path step matches the predetermined aspherical surface finish position Aspheric surface path determining step of determining an aspheric surface path, and an aspheric surface polishing step of, when it is determined in the aspheric surface path determining step that the aspherical surface path generated from the aspheric surface path step and the predetermined aspherical surface finish position coincide with each other, . In the aspherical surface path determination step, when it is determined that the aspheric surface path generated from the aspheric surface path step and the predetermined aspherical surface finish position do not match, it is preferable to regenerate the aspherical surface path through the aspheric surface path step.

The DOE pattern path generation step may include a DOE pattern path generation step of generating a DOE pattern path for forming a groove of the DOE pattern on the surface of the symmetric aspherical surface processed in the aspherical surface processing step, A DOE pattern path determination step of determining whether or not the DOE pattern path generated in the DOE pattern path step and the predetermined DOE pattern processing end position coincide with each other, And a DOE pattern machining code generation step of generating a DOE pattern machining code when it is determined that the DOE pattern path generated from the step is identical to the predetermined DOE pattern machining end position. If it is determined in the DOE pattern path determination step that the DOE pattern path generated in the DOE pattern path step and the preset DOE pattern processing end position are inconsistent, the DOE pattern path is regenerated through the DOE pattern path step desirable.

The DOE pattern path step may include a starting point calculating step of calculating a starting point of a DOE pattern for machining on a surface processed with a symmetric aspherical surface and a depth point calculating step of calculating a depth point of the DOE pattern based on the starting point calculated from the starting point calculating step Calculating a depth point of the DOE pattern based on the depth point calculated from the depth point calculating step and calculating a depth point of the DOE pattern based on the width point calculated from the depth calculating step; And an endpoint calculation step.

In addition, it is preferable that the starting point calculating step calculates the starting point Pt1 of the DOE pattern through the following equations (5) and (6).

&Quot; (5) "

&Quot; (6) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, W _i is the width of the ith DOE pattern, and Dm is the radius of the DOE pattern tool.

It is preferable that the depth point calculating step and the width calculating step calculate the depth point Pt2 and the width Pt3 of the DOE pattern using the following formula (7).

&Quot; (7) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, And d _i represents the depth of processing of the ith DOE pattern.

It is preferable that the end point calculation step calculates the end point Pt4 of the DOE pattern by using the following equations (8) and (9).

&Quot; (8) "

&Quot; (9) "

Where R, k, and A _j are constants determined by the shape of the lens as a design parameter, R is the radius of curvature, k is the conic constant, A _j is the Ashperic Coefficients, X _i is the lens radial position of the ith DOE pattern , Dm is the radius of the DOE pattern tool, and W _i is the width of the ith DOE pattern.

According to the DOE pattern processing apparatus and method for processing the DOE pattern according to the present invention, by forming the aspherical path and the DOE pattern path according to the size of the lens and the constant value of the formula received through the numerical input device and the numerical input step, The shape of the DOE pattern can be processed on the surface of the asymmetric aspherical surface, and the processing efficiency is high.

In addition, the processing accuracy of the aspheric path and the DOE pattern path is high by determining whether or not the aspherical surface path determining unit, the DOE pattern path determining unit, and the aspheric surface path determining step match the predetermined processing end positions through the DOE pattern path determining step.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the construction of a DOE pattern processing apparatus according to an embodiment of the present invention;
Fig. 2 is a schematic view showing the configuration of an aspheric surface path generating device of the DOE pattern processing equipment of Fig. 1,
FIG. 3 is a schematic view showing a configuration of a DOE pattern path generating apparatus of the DOE pattern processing apparatus of FIG. 1;
FIG. 4 is a diagram schematically showing a configuration of a DOE pattern path generating unit of the DOE pattern processing equipment of FIG. 1;
FIG. 5 is a schematic view schematically showing a state in which a lens surface is processed into an aspherical shape by using an aspheric surface machining apparatus of the DOE pattern processing equipment of FIG. 1;
6 is an enlarged schematic view showing a state in which the lens surface is processed into an aspherical shape by using an aspheric surface machining apparatus of the DOE pattern processing equipment of FIG.
FIG. 7 is a schematic view schematically showing a state in which a DOE pattern is processed on the surface of a lens using a DOE pattern processing apparatus of the DOE pattern processing apparatus of FIG. 1;
FIG. 8 is a view showing a step of stepwise showing the state of processing the DOE pattern on the lens surface by the DOE pattern processing apparatus of the DOE pattern processing apparatus of FIG. 1,
9 is a flowchart showing a DOE pattern processing method according to an embodiment of the present invention,
10 is a flowchart showing a DOE pattern path generation step of the DOE pattern processing method shown in FIG. 9,
FIG. 11 is a graph showing an aspheric path and a DOE pattern path generated by using the DOE pattern processing apparatus of the present invention and the processing method thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, at the time of the present application, It should be understood that variations can be made.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 8, a DOE pattern processing apparatus 10 according to an embodiment of the present invention processes a lens surface L into a shape of a symmetrical aspherical surface, processes a DOE pattern on the surface of the processed symmetric aspherical surface . The DOE pattern processing apparatus 10 includes a numerical value inputting apparatus 100, an aspheric surface path generating apparatus 200, an aspherical surface processing apparatus 300, a DOE pattern path generating apparatus 400, and a DOE pattern processing apparatus 500 .

The numerical value inputting apparatus 100 receives an aspherical shape for processing the lens surface L and an information value for the DOE pattern. It is preferable that the numerical value inputting apparatus 100 receives the design value for the aspheric shape, the value for the aspheric shape, the shape of the tool for processing the DOE pattern, and the data for the DOE pattern.

2, the aspheric surface path generation apparatus 200 includes an aspheric surface path (A) for processing the lens surface L into a symmetrical aspherical surface shape corresponding to the information value input from the numerical value input apparatus 100, ). The aspheric surface path generation apparatus 200 may include an aspheric surface path generation unit 210, an aspheric surface path determination unit 220, and an aspheric surface polishing code generation unit 230.

The aspheric surface path generation unit 210 generates an aspheric surface path A corresponding to the information value input by the numerical value input apparatus 100. [ The aspherical surface path generation section 210 calculates the movement path of the tool center point Xt and Zt of the aspherical surface tool C that processes the lens surface L into the shape of the symmetric aspherical surface in the aspheric path A. [ The aspheric surface path A can be calculated by utilizing the tangent line between the aspheric surface L of the lens and the surface of the aspherical surface tool C to form the lens surface L as a symmetric aspheric surface, (1) to (4).

Here, the contact angle between the aspherical surface L of the lens and the surface of the aspherical tool C can be calculated using the following equations (2) and (3) substituting the equation (1) have.

That is, the tool center point Xt, Zt can be calculated using the following equation (4) by using the contact angle and the geometric relationship from the tangent line of the aspheric surface L of the lens and the surface of the aspherical tool C:

는 렌즈 표면의 접선 기울기, D_t는 비구면공구(C)의 반경을 나타낸다. Wherein, R, k, A _j is a constant determined in accordance with the shape as the design parameters of the lens, R is the curvature radius, k is the conic constant, A _j is the Ashperic Coefficients, x is (5 radial coordinate of the lens r), z is the height direction coordinate of the lens,

Is the tangential slope of the lens surface, and D _t is the radius of the aspherical tool (C).

The aspheric path determining unit 220 determines whether or not the aspheric surface path A generated by the aspheric surface path generating unit 210 matches the preset aspherical surface finish position. The predetermined aspherical surface finish position can be set by the information value input from the numerical value inputting device 100. [ That is, the aspheric path determining unit 220 determines whether or not the aspherical path A generated by the aspheric path generating unit 210 has reached the predetermined aspherical surface finishing position and is matched.

When it is determined in the aspheric surface path determination unit 220 that the aspheric surface path A generated by the aspheric surface path generation unit 210 and the preset aspheric surface finish position do not match, the aspheric surface path generation unit 210 Thereby regenerating the aspheric surface path A. That is, the aspheric path determining unit 220 continuously generates the aspheric surface path A until the aspheric surface path A generated by the aspheric surface path generating unit 210 reaches and coincides with the predetermined aspherical surface processing end position do.

The aspheric surface polishing code generation unit 230 determines that the aspherical surface path determination unit 220 determines that the aspheric surface path A generated from the aspheric surface path generation unit 210 and the predetermined aspherical surface finish position match , An aspherical surface polishing code is generated. The aspherical surface polishing code is for polishing the lens surface L by driving the aspherical surface tool C, and it is preferable to transmit the aspherical surface polishing code to the aspheric surface machining apparatus 300 to be described later.

It is preferable that the aspheric surface path generation unit 210 is adapted to generate the aspherical surface path A for roughing, centering, and finishing so as to form the processed lens surface L so as to be smooth.

The aspheric surface machining apparatus 300 processes the lens surface L into a symmetric aspherical surface along the aspheric path A generated by the aspheric surface path generating apparatus 200. [ That is, the aspheric surface machining apparatus 300 receives the aspherical surface polishing code generated from the aspheric surface polishing code generating unit 230 and processes the lens surface L into a symmetric aspheric surface using the aspherical surface tool C.

In the case where the lens surface is convex, it is preferable to apply a fly-cutter and a ball-mill to the aspherical surface tool C, and to apply a ball-mill when the lens surface is concave Lt; / RTI >

Referring to FIG. 3, the DOE pattern path generating apparatus 400 generates a DOE pattern path D corresponding to the information value input from the numerical value inputting apparatus 100. The DOE pattern path generating apparatus 400 generates a DOE pattern path D for processing the groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining apparatus 300. [ The DOE pattern path generating apparatus 400 may include a DOE pattern path generating unit 410, a DOE pattern path determining unit 420, and a DOE pattern processing code generating unit 430.

4, the DOE pattern path generating unit 410 generates a DOE pattern on the surface of the asymmetric aspherical surface processed in the aspheric working apparatus 300, corresponding to the information value input from the numerical value inputting apparatus 100, And a DOE pattern path D for forming a groove of the groove. That is, the DOE pattern path generating unit 410 generates a DOE pattern path M for forming a groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining apparatus 300, (D). The DOE pattern path generating unit 410 may further include a starting point calculating unit 411, a depth point calculating unit 412, a width calculating unit 413 and an end point calculating unit 414. [

The starting point calculating means 411 calculates the starting point Pt1 of the DOE pattern for machining on the surface machined to the symmetric aspherical surface. The starting point calculating means 411 preferably calculates the starting point Pt1 of the DOE pattern by using the following equations (5) and (6).

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, Position, W _i is the width of the ith DOE pattern, and Dm is the radius of the DOE pattern tool M.

The depth point calculating means 412 calculates the depth point Pt2 of the DOE pattern on the basis of the starting point Pt1 calculated from the starting point calculating means 411. [ The width calculating means 413 calculates the width Pt3 of the DOE pattern on the basis of the depth point Pt2 calculated by the depth point calculating means 412. [

It is preferable that the depth point calculating means 412 and the width calculating means 413 calculate the depth point Pt2 and the width Pt3 of the DOE pattern by using the following expression (7).

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, And d _i represents the depth of processing of the ith DOE pattern.

The end point calculating means 414 calculates the end point Pt4 of the DOE pattern on the basis of the width Pt3 calculated from the width calculating means 413. The end point calculating means 414 preferably calculates the end point Pt4 of the DOE pattern by using the following equations (8) and (9).

Where R, k, and A _j are constants determined by the shape of the lens as a design parameter, R is the radius of curvature, k is the conic constant, A _j is the Ashperic Coefficients, X _i is the lens radial position of the ith DOE pattern , Dm is the radius of the DOE pattern tool (M), and W _i is the width of the ith DOE pattern.

8, the DOE pattern path generating apparatus 400 moves the DOE pattern tool M in the order of the start point Pt1, the depth point Pt2, the width point Pt3, and the end point Pt4 The DOE pattern path D is calculated so as to form the groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining apparatus 300. [

The DOE pattern path generating apparatus 400 may further include a coordinate transforming unit. The coordinate transforming unit transforms the coordinates of the DOE pattern path D generated by the DOE pattern path generating unit 410 so that the coordinates of the DOE pattern path D set on the basis of the position of the lens L will be described (To be described later) according to the orientation setting of the DOE pattern processing apparatus 500. Therefore, the final DOE pattern path D can be generated through the coordinate transformation unit.

The DOE pattern path determining unit 420 determines whether or not the DOE pattern path D generated by the DOE pattern path generating unit 410 matches the predetermined DOE pattern processing end position. The predetermined DOE pattern processing end position can be set by the information value input from the numerical value inputting apparatus 100. [ That is, the DOE pattern path determining unit 420 determines whether or not the DOE pattern path D generated by the DOE pattern path generating unit 410 reaches or agrees with a predetermined aspherical surface finish position .

The DOE pattern processing code generation unit 430 generates the DOE pattern processing code by using the DOE pattern path D generated by the DOE pattern path generation unit 410 and the predetermined DOE pattern processing end position The DOE pattern processing code is generated. The DOE pattern machining code is for machining a DOE pattern on the lens surface L by driving the DOE pattern tool M. The DOE pattern machining code is transmitted to the DOE pattern machining apparatus 500 to be described later .

 If the DOE pattern path determination unit 420 determines that the DOE pattern path D generated by the DOE pattern path generation unit 410 and the predetermined DOE pattern processing end position do not coincide with each other, It is preferable to regenerate the DOE pattern path D through the generation unit 410. [ That is, the DOE pattern path determination unit 420 determines whether or not the DOE pattern path D generated by the DOE pattern path generation unit 410 reaches the predetermined DOE pattern processing end position, ).

The DOE pattern path generating unit 410 is adapted to generate a DOE pattern path D for roughing, centering, and finishing so as to form a smooth lens surface L on which the DOE pattern is processed Lt; / RTI >

 The DOE pattern processing apparatus 500 processes the groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path D generated by the DOE pattern path generating apparatus 400. That is, the DOE pattern machining apparatus 500 receives the DOE pattern machining code generated from the DOE pattern machining code generating section 430, and forms a DOE pattern on the lens surface of the symmetric aspheric surface using the DOE pattern tool M. [ . The DOE pattern tool M may preferably be a micro tool.

Hereinafter, the DOE pattern processing method (S10) according to the embodiment of the present invention will be described in detail with reference to FIGS. 9 to 11. FIG. The DOE pattern processing method S10 includes a numerical value input step S100, an aspheric surface path generating step S200, an aspheric surface processing step S300, a DOE pattern path generating step S400, and a DOE pattern processing step S500 can do.

The numerical value input step S100 is a step of inputting an aspherical shape for processing the lens surface L and an information value for the DOE pattern. The numerical value input step (S100) preferably inputs design values for the aspheric shape, values for the aspheric shape, shape of the tool for processing the DOE pattern, and data for the DOE pattern.

The aspheric surface path generation step S200 generates an aspheric surface path A for processing the lens surface L into a symmetric aspheric surface shape corresponding to the information value input in the numerical value input step S100. The aspheric surface path generation step S200 may include an aspheric surface path step S210, an aspheric surface path determination step S220, and an aspheric surface polishing code generation step S230.

The aspherical surface path step S210 creates an aspheric surface path A corresponding to the information value input in the numerical value input step S100. The aspherical surface path step S210 calculates the path of movement of the tool center point Xt, Zt of the aspherical surface tool C that processes the lens surface L into the shape of a symmetric aspherical surface by the aspheric path A. [ The aspheric surface path A can be calculated by utilizing the tangent line between the aspheric surface L of the lens and the surface of the aspherical surface tool C to form the lens surface L as a symmetric aspheric surface, (1) to (4).

[Equation 1]

Here, the contact angle between the aspherical surface L of the lens and the surface of the aspherical tool C can be calculated by differentiating (Equation 1) using the following Equations 2 and 3 have.

&Quot; (2) "

&Quot; (3) "

 That is, the tool center point Xt, Zt can be calculated using the following equation (4) by using the contact angle and the geometric relationship from the tangent line of the aspheric surface L of the lens and the surface of the aspherical tool C:

&Quot; (4) "

Wherein, R, k, A _j is a constant determined in accordance with the shape as the design parameters of the lens, R is the curvature radius, k is the conic constant, A _j is the Ashperic Coefficients, x is (5 radial coordinate of the lens r represents the height direction coordinate of the lens, z represents the tangential slope of the lens surface, and D _t represents the radius of the aspherical tool (C).

The aspherical surface path determination step S220 determines whether or not the aspheric surface path A generated in the aspheric surface path step S210 and the preset aspherical surface finish position coincide with each other. The predetermined aspherical surface finish position may be set by the information value input from the numerical value input step S100. That is, the aspherical surface path determination step S220 determines whether or not the aspheric surface path A generated from the imaginary aspherical surface path step S210 reaches and coincides with the predetermined aspherical surface machining end position.

If it is determined that the aspherical surface path A generated from the aspheric surface path step S210 and the predetermined aspherical surface finish position do not match in the aspheric surface path determination step S220, Regenerates the path (A). That is, the aspherical surface path determination step S220 continues to generate the aspherical surface path A until the aspheric surface path A generated from the aspheric surface path step S210 reaches the predetermined aspherical surface finish position .

The aspheric surface polishing code generation step S230 may be performed in the aspherical surface path determination step S220 if it is determined that the aspheric surface path A generated from the aspheric surface path step S210 matches the pre- Thereby generating an aspherical surface polishing code. The aspherical surface polishing code is for polishing the lens surface L by driving the aspherical surface tool C, and it is preferable to transmit the aspherical surface polishing code to the aspheric surface machining apparatus 300 to be described later.

Meanwhile, it is preferable that the aspheric surface path step S210 is applied so as to generate the aspherical surface path A for roughing, centering, and finishing so as to form the processed lens surface L so as to be smooth.

The aspherical surface processing step S300 processes the lens surface L into a symmetric aspherical surface along the aspheric path A generated in the aspheric surface path generating step S200. That is, the aspherical surface machining step (S300) receives the aspherical surface polishing code generated from the aspherical surface polishing code generating step (S230) and processes the lens surface (L) into a symmetric aspheric surface using the aspherical surface tool (C).

In the case where the lens surface is convex, it is preferable to apply a fly-cutter and a ball-mill to the aspherical surface tool C, and to apply a ball-mill when the lens surface is concave Lt; / RTI >

The DOE pattern path generation step (S400) generates a DOE pattern path (D) corresponding to the information value input in the numerical value input step (S100). In more detail, the DOE pattern path creation step (S400) creates a DOE pattern path (D) for processing the groove of the DOE pattern on the surface of the symmetric aspherical surface processed in the aspherical surface processing step (S300). The DOE pattern path generation step S400 may include a DOE pattern path step S410, a DOE pattern path determination step S420, and a DOE pattern processing code generation step S430.

The DOE pattern path step S410 may include a step of forming a groove of a DOE pattern on the surface of the asymmetric aspheric surface processed in the aspheric surface processing step S300 in correspondence with the information value input in the numerical value input step S100 And generates a DOE pattern path (D). That is, the DOE pattern path step S410 is a step of moving the path of processing the DOE pattern tool M for forming the groove of the DOE pattern on the surface of the symmetric aspherical surface processed in the aspherical surface processing step S300 to the DOE pattern path (D). The DOE pattern path step S410 may include a starting point calculating step S411, a depth point calculating step S412, a width calculating step S413, and an end point calculating step S414.

The starting point calculating step S411 calculates the starting point Pt1 of the DOE pattern for machining on the surface machined to the symmetric aspherical surface. The starting point calculating step S411 calculates the starting point Pt1 of the DOE pattern using the following equations (5) and (6).

&Quot; (5) "

&Quot; (6) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, Position, W _i is the width of the ith DOE pattern, and Dm is the radius of the DOE pattern tool M.

The depth point calculating step S412 calculates a depth point Pt2 of the DOE pattern on the basis of the starting point Pt1 calculated from the starting point calculating step. The width calculating step S413 calculates the width Pt3 of the DOE pattern based on the depth point Pt2 calculated from the depth point calculating step.

The depth point calculating step S412 and the width calculating step S413 calculate the depth point Pt2 and the width Pt3 of the DOE pattern using the following equation (7).

&Quot; (7) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, And d _i represents the depth of processing of the ith DOE pattern.

The ending point calculating step S414 calculates an end point Pt4 of the DOE pattern based on the width Pt3 calculated from the width calculating unit. The end point calculation step S414 calculates the end point Pt4 of the DOE pattern using the following equations (8) and (9).

&Quot; (8) "

&Quot; (9) "

Where R, k, and A _j are constants determined by the shape of the lens as a design parameter, R is the radius of curvature, k is the conic constant, A _j is the Ashperic Coefficients, X _i is the lens radial position of the ith DOE pattern , Dm is the radius of the DOE pattern tool (M), and W _i is the width of the ith DOE pattern.

That is, the DOE pattern path generation step S400 is performed by moving the DOE pattern tool M in the order of the start point Pt1, the depth point Pt2, the width point Pt3, and the end point Pt4, The DOE pattern path D is calculated so as to form the grooves of the DOE pattern on the surface of the symmetric aspherical surface processed in the step of FIG.

Meanwhile, the DOE pattern path generating step (S400) may further include a coordinate transforming unit. The coordinate transforming unit transforms the coordinates of the DOE pattern path D generated from the DOE pattern path step S410 so that the coordinates of the DOE pattern path D set based on the position of the lens L will be described later ) In the DOE pattern processing step (step 500). Therefore, the final DOE pattern path D can be generated through the coordinate transformation unit.

The DOE pattern path determination step S420 determines whether or not the DOE pattern path D generated in the DOE pattern path step S410 matches the predetermined DOE pattern processing end position. The pre-set DOE pattern machining end position may be set by the information value inputted from the numerical value input step S100. That is, the DOE pattern path determination step S420 determines whether the DOE pattern path D generated in the DOE pattern path step S410 reaches the predetermined aspherical surface finish position and whether or not the DOE pattern path D is matched.

The DOE pattern machining code generation step (S430) If it is determined that the DOE pattern path D generated from the DOE pattern path step S410 and the predetermined DOE pattern processing end position match in the DOE pattern path determination step S420, do. The DOE pattern machining code is for machining a DOE pattern on the lens surface L by driving the DOE pattern tool M. The DOE pattern machining code is transmitted to a DOE pattern machining step S500 to be described later .

If it is determined that the DOE pattern path D generated from the DOE pattern path step S410 and the predetermined DOE pattern processing end position do not match in the DOE pattern path determination step S420, It is preferable to regenerate the DOE pattern path D through step S410. That is, the DOE pattern path determination step S420 determines whether or not the DOE pattern path D generated from the DOE pattern path step S410 reaches the predetermined DOE pattern processing end position, Lt; / RTI >

In the meantime, the DOE pattern path step S410 is to apply a DOE pattern path D for roughing, centering, and finishing so as to form a smooth lens surface L on which the DOE pattern is processed Lt; / RTI >

The DOE pattern processing step S500 processes the groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path D generated in the DOE pattern path generating step S400. That is, the DOE pattern processing step (S500) receives the DOE pattern machining code generated from the DOE pattern machining code generating step (S430) and forms a DOE pattern on the lens surface of the asymmetric aspheric surface using the DOE pattern tool (M) . The DOE pattern tool M may preferably be a micro tool.

According to the DOE pattern processing apparatus and method for processing the DOE pattern according to the present invention, by forming the aspherical path and the DOE pattern path according to the size of the lens and the constant value of the formula received through the numerical input device and the numerical input step, The shape of the DOE pattern can be processed on the surface of the asymmetric aspherical surface, and the processing efficiency is high.

In addition, the processing accuracy of the aspheric path and the DOE pattern path is high by determining whether or not the aspherical surface path determining unit, the DOE pattern path determining unit, and the aspheric surface path determining step match the predetermined processing end positions through the DOE pattern path determining step.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: DOE pattern processing equipment
100: numerical value input device 200: aspherical surface path generating device
210: Aspheric surface path generation unit 220: Aspherical surface path determination unit
230: Aspherical surface polishing code generation unit 300: Aspherical surface machining apparatus
400: DOE pattern path generating unit 410: DOE pattern path generating unit
411: starting point calculating means 412: depth point calculating means
413: Width calculation means 414: End point calculation means
420: DOE pattern path determination unit 430: DOE pattern processing code generation unit
500: DOE pattern processing apparatus A: Aspherical surface path
C: Aspherical tool D: DOE pattern path
L: Lens M: DOE pattern tool

Claims (20)

A DOE pattern processing apparatus for processing a symmetrical aspherical surface and a DOE pattern on a lens surface,
A numerical value input device for receiving an aspherical shape for processing the lens surface and an information value of a DOE pattern;
An aspherical surface path generating device for generating an aspheric path for processing the lens surface into a symmetrical aspherical surface shape corresponding to the information value input by the numerical value inputting device;
An aspheric surface machining device for machining the lens surface to a symmetric aspheric surface along an aspherical surface path generated by the aspheric surface path generating device;
A DOE pattern path generating device for generating a DOE pattern path for processing the groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining device in correspondence with the information value inputted by the numerical value inputting device; And
And a DOE pattern processing device for processing the groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path generated by the DOE pattern path generating device,
The DOE pattern path generating apparatus includes:
A DOE pattern path generating unit for generating a DOE pattern path for forming a groove of the DOE pattern on the surface of the asymmetric aspheric surface processed by the aspheric surface machining apparatus,
A DOE pattern path determination unit for determining whether or not the DOE pattern path generated by the DOE pattern path generating unit matches a predetermined DOE pattern processing end position,
And a DOE pattern processing code generation unit for generating a DOE pattern processing code when it is determined by the DOE pattern path determination unit that the DOE pattern path generated by the DOE pattern path generation unit matches a predetermined DOE pattern processing end position In addition,
Wherein the DOE pattern path determination unit determines that the DOE pattern path generated by the DOE pattern path generation unit and the predetermined DOE pattern processing end position do not match with each other, Pattern processing equipment. The method according to claim 1,
Wherein the numerical value input device comprises:
A design value for an aspherical shape, a value for a shape of a tool for processing an aspheric shape and a DOE pattern, and a DOE pattern processing facility for receiving data on the DOE pattern. The method according to claim 1,
The aspherical surface path generation device includes:
An aspheric surface path generation unit for generating an aspherical surface path corresponding to the information value input by the numerical value input device,
An aspherical surface path determination unit for determining whether or not the aspheric surface path generated by the aspheric surface path generation unit matches a predetermined aspherical surface finish position,
Wherein the aspherical surface path determination unit includes an aspheric surface polishing code generation unit that generates an aspheric surface polishing code when it is determined that the aspheric surface path generated from the aspheric surface path generation unit matches a predetermined aspherical surface processing end position. The method of claim 3,
Wherein the aspherical surface path determination unit regenerates the aspherical surface path through the aspheric surface path generation unit when it is determined that the aspheric surface path generated from the aspheric surface path generation unit and the predetermined aspherical surface finish position do not match. delete delete The method according to claim 1,
Wherein the DOE pattern path generating unit comprises:
Starting point calculating means for calculating a starting point of a DOE pattern for machining on a surface machined to a symmetrical aspherical surface,
Depth point calculating means for calculating a depth point of the DOE pattern based on the starting point calculated by the starting point calculating means,
Width calculating means for calculating a width of the DOE pattern based on the depth point calculated by the depth point calculating means,
And an end point calculating means for calculating an end point of the DOE pattern based on the width calculated from the width calculating means. The method of claim 7,
The starting point calculating means calculates,
DOE pattern processing equipment for calculating the starting point Pt1 of the DOE pattern using the following equations (5) and (6)
&Quot; (5) "

&Quot; (6) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, W _i is the width of the ith DOE pattern, and Dm is the radius of the DOE pattern tool. The method of claim 8,
The depth-point calculating means and the depth-
DOE pattern processing equipment for calculating the depth point Pt2 and the width Pt3 of the DOE pattern using the following formula (7)
&Quot; (7) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, And d _i represents the depth of processing of the ith DOE pattern. The method of claim 9,
The end point calculation means calculates,
DOE pattern processing equipment for calculating the end point (Pt4) of the DOE pattern through the following equations (8) and (9)
&Quot; (8) "

&Quot; (9) "

Where R, k, and A _j are constants determined by the shape of the lens as a design parameter, R is the radius of curvature, k is the conic constant, A _j is the Ashperic Coefficients, X _i is the lens radial position of the ith DOE pattern , Dm is the radius of the DOE pattern tool, and W _i is the width of the ith DOE pattern. A DOE pattern processing method for processing a symmetrical aspherical surface and a DOE pattern on a lens surface,
A numerical value input step of inputting information values of an aspherical shape and a DOE pattern for processing the lens surface;
An aspherical surface path generation step of generating an aspheric surface path for processing the lens surface into a symmetric aspherical surface shape corresponding to the information value input in the numerical value input step;
An aspherical surface machining step of machining the lens surface to a symmetric aspheric surface along the aspherical surface path generated in the aspherical surface path generating step;
A DOE pattern path generating step of generating a DOE pattern path for processing a groove of the DOE pattern on the surface of the symmetric aspherical surface in correspondence with the information value inputted in the numerical value input step; And
And a DOE pattern processing step of processing the groove of the DOE pattern on the surface of the symmetric aspherical surface according to the DOE pattern path generated in the DOE pattern path generating step,
In the DOE pattern path generation step,
A DOE pattern path step for generating a DOE pattern path for forming a groove of a DOE pattern on a surface of a symmetric aspherical surface processed in the aspherical surface processing step in correspondence with the information value inputted in the numerical value input step,
A DOE pattern path determination step of determining whether or not the DOE pattern path generated in the DOE pattern path step and the predetermined DOE pattern processing end position coincide with each other,
And a DOE pattern machining code generation step of generating a DOE pattern machining code when it is determined in the DOE pattern path determination step that the DOE pattern path generated from the DOE pattern path step and the predetermined DOE pattern machining end position coincide with each other In addition,
If it is determined in the DOE pattern path determination step that the DOE pattern path generated in the DOE pattern path step and the predetermined DOE pattern processing end position do not match, a DOE pattern path for regenerating the DOE pattern path through the DOE pattern path step Processing method. The method of claim 11,
In the numerical value input step,
A design value for an aspherical shape, a value for a shape of a tool for processing an aspheric shape and a DOE pattern, and a DOE pattern processing method for inputting data for the DOE pattern. The method of claim 11,
Wherein the aspheric surface path generation step includes:
An aspherical surface path step of generating an aspheric surface path corresponding to the information value input in the numerical value input step,
An aspherical surface path determination step of determining whether or not the aspherical surface path generated in the aspherical surface path step and the predetermined aspherical surface machining end point match with each other,
Wherein the step of determining the aspherical surface includes an aspheric surface polishing code generating step of generating an aspheric surface polishing code when it is determined that the aspheric surface path generated from the aspherical surface path step and the predetermined aspherical surface finish position coincide with each other. 14. The method of claim 13,
Wherein the aspherical surface path determination step regenerates the aspherical surface path through the aspheric surface path step if it is determined that the aspheric surface path generated from the aspheric surface path step and the predetermined aspherical surface finish position do not match. delete delete The method of claim 11,
The DOE pattern path step includes:
A starting point calculating step of calculating a starting point of a DOE pattern for machining on a surface machined to a symmetrical aspherical surface,
A depth point calculating step of calculating a depth point of the DOE pattern based on a starting point calculated from the starting point calculating step,
A depth calculating step of calculating a depth of the DOE pattern based on the depth point calculated from the depth point calculating step;
And an end point calculating step of calculating an end point of the DOE pattern on the basis of the width calculated from the width calculating step. 18. The method of claim 17,
The starting point calculating step may include:
A DOE pattern processing method for calculating a starting point (Pt1) of a DOE pattern through the following equations (5) and (6)
&Quot; (5) "

&Quot; (6) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, W _i is the width of the ith DOE pattern, and Dm is the radius of the DOE pattern tool. 19. The method of claim 18,
The depth-point calculating step and the width-
DOE pattern processing method for calculating the depth point Pt2 and the width point Pt3 of the DOE pattern using the following formula (7)
&Quot; (7) "

K is a conic constant, A _j is an Ashperic Coefficients, and X _i is a lens radial direction of the i-th DOE pattern, where R, k, and A _j are constants determined by the shape as a design factor of the lens, And d _i represents the depth of processing of the ith DOE pattern. The method of claim 19,
Wherein the end point calculating step includes:
A DOE pattern processing method for calculating an end point (Pt4) of a DOE pattern by using the following equations (8) and (9)
&Quot; (8) "

&Quot; (9) "

Where R, k, and A _j are constants determined by the shape of the lens as a design parameter, R is the radius of curvature, k is the conic constant, A _j is the Ashperic Coefficients, X _i is the lens radial position of the ith DOE pattern , Dm is the radius of the DOE pattern tool, and W _i is the width of the ith DOE pattern.

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