Distortion mapping correction in aspheric null testing

M. Novak, C. Zhao, J. H. Burge College of Optical Sciences, 1630 East University Boulevard, Tucson, AZ, 85721

ABSTRACT

We describe methods to correct both symmetric and asymmetric distortion mapping errors induced by null testing elements such as holograms or null lenses. We show experimental results for direct measurement and correction of symmetric mapping distortion, as well as an example result for analytical mapping performed using an orthogonal set of vector polynomials for asymmetric correction. The empirical determination of symmetric distortion is made via calculation from predicted and measured changes to aberrations induced via known changes to the testing point.

1. INTRODUCTION Aspheric primary mirrors are popular for astronomical telescope systems. These mirrors are polished to aspheric shapes to help minimize the overall length of the telescope system and provide additional optical correction for improved telescope performance. Optical testing with high accuracy is necessary, from as early a point in the fabrication process as is feasible, to efficiently converge to the proper finished optical surface. One potential obstacle encountered when fabricating aspheric surfaces is distortion present when imaging through null elements in the optical test. Distortion arises due to imperfect imaging through a null lens system and other optics in an interferometer or through a transmission CGH. The presence of distortion diminishes accuracy by mapping surface features to incorrect radial positions on the image plane. In this paper, we describe a method used to determine symmetric distortion which may prove practical for large asphere testing, as well as a more general correction method for asymmetric distortion. These techniques can be used to enable efficient testing of aspheric optical surfaces.

2. SYMMETRIC DISTORTION It is useful to know how much distortion is present in interferometric measurement data. The distortion may arise not only from the distortion inherent to the null optics used in the asphere test, but also from the diverging and collimating optics as well as any internal optical elements in the interferometer. In this section, we present a method to determine distortion applicable in cases of rotational symmetry in the image of the part under test. We hope this method can provide an alternative efficient means of determining distortion for correction of optical testing data.

Interferometry XIV: Techniques and Analysis, edited by Joanna Schmit, Katherine Creath, Catherine E. Towers, Proc. of SPIE Vol. 7063, 706313, (2008) · 0277-786X/08/$18 · doi: 10.1117/12.798151

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2.1 Determination via Aberration Monitoring To illustrate, we first considered a hyperbolic lens tested against a perfect spherical surface. The layout is shown in the diagram in Figure 1.

Figure 1. Hyperbolic lens and spherical return mirror. Consider that distortion present in such an optical system causes a mapping of mirror surface coordinates to a distorted coordinate frame in the image. This mapping is not at 1:1 from mirror surface to detector pixel coordinates. Instead, the mapping can be written as

2(1 )i m mm Dρ ρ ρ= + , (1)

where

11

mD

=+

, and D is the distortion expressed as percent/100.

If a known focus shift is made in the optical test, we have a wavefront change that is expressed as

2( )m m mW Aρ ρ= , (2)

which maps to

42 2)21()( iii DADAWi ρρρ −+= . (3) Here, A is the wavefront focus coefficient and D is the total linear distortion present in the imaging system (including the interferometer optics in addition to the null optics). We have ignored alignment errors in this wavefront expression. A known amount of focus in the wavefront contributes focus and spherical aberration to the measured result. By controlling wavefront focus and monitoring the resulting spherical aberration, an estimate of the system distortion can be made. Once the distortion is determined, a polynomial transformation can be applied to remap the surface data appropriately.

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Figure 2 contains a plot of fourth order spherical aberration as a function of focus position in the optical test illustrated in Figure 1. These data can be used to write a set of equations relating wavefront coefficients for spherical (Z9) and focus (Z4) aberrations for individual measurement cases of varying defocus. This set of equations can then be used to calculate wavefront coefficients in order to estimate the system distortion. In practice, we hope this technique will allow for estimation of the contribution of distortion that cannot be modeled (i.e., distortion from imaging optics within the interferometric system used for testing that are of unknown design or quality), for large aspheric surfaces where building an accurate fiducial mask may be challenging as well as a safety risk to the surface.

Figure 2. Plot of Z9 vs. test point shift for hyperbolic lens system 2.2 Preliminary Experimental Result Based on This Method To show an example of this process, measurements were made to determine the distortion in the IR optical test of a 4.3 m hyperbolic primary mirror currently in fabrication in our facility. To check the true distortion value, eight fiducial masks were placed on the mirror at known spacing and a map of the modulation was made to determine the image position of these fiducials relative to their actual mirror position. A photograph of the fiducials used for this traditional method of distortion determination is shown in Figure 3.

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Figure 3. 4.3 m primary mirror with eight fiducial rings.

Calculation based on these data provided an estimate of the distortion of the optical system of approximately –8% (D = -0.08). The null lens was determined via modeling to have approximately -3.3% distortion; this indicates a significant distortion component is present in the interferometer optics. After this initial determination of distortion, measurements were made of the optical surface, and aberrations were monitored to keep track of the changing Zernike terms of interest (Z4 and Z9 for focus and spherical aberration). Measured and predicted values of Z9 are plotted as a function of test point shift in Figure 4.

Predicted and Measured Z9 vs. Test Point Shift

-0.8000

-0.6000

-0.4000

-0.2000

0.0000

0.2000

0.4000

0.6000

-6.0000 -5.0000 -4.0000 -3.0000 -2.0000 -1.0000 0.0000 1.0000 2.0000 3.0000 4.0000 5.0000

Test Point Shift [mm]

Pred

icte

d an

d M

easu

red

Z9 [m

icro

ns] Z9 (design/model) microns

Z9 measured [microns]

Figure 4. Z9 (predicted for null lens only and measured including total optical system) vs. test point shift for IR

interferometer measurement. These data indicate a slightly larger value of distortion present in the system than is indicated in the predicted change with testing point. We consider this to be evidence of the distortion due to the internal optical system of the interferometer. Calculation from these data gave distortion of -6.8% (D = -0.068).

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The difference from the traditional correction may be attributed to limitations due to the imaging optics in our IR interferometer. Also, the instrument noise floor is not much lower than the values of spherical aberration being measured in this case.

3. ASYMMETRIC DISTORTION In this section, we describe a method used to correct asymmetric distortion in an optical null test. We believe this method can be applied in general cases where a transmission CGH test is used to fabricate off axis aspheric surfaces; the distortion in this case does not preserve rotational symmetry. 3.1 Vector Polynomial Mapping Correction We now present an example of a more general distortion correction based on vector polynomial coordinate mapping. For this example, we consider the testing of an off axis parabola segment using a CGH null used in transmission. In this optical test, distortion from the CGH causes a highly irregular image which must be corrected to avoid major difficulties in accurately figuring the proper location on the optical surface. The image of the part under test is distorted asymmetrically as shown in Figure 5. Mapping distortion:

Test optic Image

Measured map:

Figure 5. Points on a test optic and their corresponding location in the image, as well as an illustration of a distorted surface map. The mapping relationship between the test optic and its distorted image is determined solely by the optics in between. The mapping of radial coordinates can be described as:

( ')r Mapping r=r r ,

where rr defines a point on the test optic, (x, y); and 'rr defines a point on the camera, (x’, y’).

The following steps are taken to determine this mapping relationship:

x’

y’

x

y

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\::::::::::::Z i \—. N N \ I I I I I /N\ \ I I I II //Z

1111/ / / I I I I \ N//I 11 0

/7 / / 1 1 1 1 \ \ 7/,'/ / 1 1 1 1 \ 7

N\\ \ I 1 1 11/7N /1/ /'Ii a

a @1

1. Pick a set of base functions to describe the mapping relations

2. Obtain r and r’ for a series of points

3. Fit coefficients for the base functions describing the mapping relations between coordinates. We developed a series of orthonormal vector polynomials over a unit circle based on the gradient of Zernike polynomials. Pictures of a set of 12 of these polynomials are shown in Table 1.

2Sr

3Sr

4Sr 5S

r

6Sr

7Sr

8Sr

9Sr

10Sr

11Sr

12Sr

13Sr

Table 1. First 12 vector polynomials plotted on a unit circle.

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SSSSSSSSSTS_: : : : : :-: : : : :S S S S S S S S S S S 5 •S

S S S S S S S S S S S S S •

.1

These vector polynomials are excellent candidates for the base functions for describing the mapping relations in an asymmetrically distorted optical test image. We have used these polynomials with success in fitting the mapping relations for the null test of the off-axis parabola segment (whose distorted map is shown in Figure 5.). To obtain the r and r’ pairs, a mask with regularly distributed holes can be laid on the test optic and the holes can then be located on the camera. The mask is shown in Figure 6.

Figure 6. Fiducial mask with 1” diameter holes located on a grid of 10” spacing.

Once the base functions have been chosen and data for the r and r’ pairs has been measured, fitting the mapping relationship is straightforward. We have written Matlab code to fit the mapping coefficients via a least squares method. The resulting corrected surface map is shown below in Figure 7.

Figure 7. Surface map of the test optic, a distortion-corrected version of the one shown in Figure 1.

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4. CONCLUSION We have described a method for empirical determination of rotationally symmetric distortion and shown results of an experimental determination of distortion made in this way. There was approximately 15% difference between this experimental result and the estimation of distortion based on a traditional fiducial-based calculation. We consider this to be a limitation due to the imaging and relay optics in the IR interferometric measurement we are using at the current state of fabrication of the mirror. We have also shown an example of correction of asymmetric distortion based on an analytical vector polynomial mapping of test optic to image coordinates which works very well for the correction of non-rotationally symmetric distortion in optical testing data. These methods can be used to provide accurate knowledge of the position of surface features in order to efficiently fabricate aspheric optical surfaces.

REFERENCES L.A. Selberg, “Interferometer accuracy and precision” Metrology: Figure and Finish, B. Truax, Editor. Proceedings SPIE 749 8-18, 1987. J.H. Burge, “Advanced techniques for measuring primary mirrors for astronomical telescopes”, Ph.D. dissertation, 1993. C. Zhao, J. H. Burge, “An Orthonormal Series of Vector Polynomials in a Unit Circle, Part II”, Opt. Express 16, 6586-6591 (2008). C. Zhao, J. H. Burge, “An Orthonormal Series of Vector Polynomials in a Unit Circle, Part I”, Opt. Express 15, 18014-18024 (2007).

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