Design and optimization of compact freeform lens array for laser beam splitting SPIE 9131 6 2014
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"Design and optimization of compact freeform lens array for laser beam splitting: a case study in optimal surface representation", in Optical Modelling and Design III, Frank Wyrowski; John T. Sheridan; Jani Tervo; Youri Meuret, Editors, Proceedings of SPIE Vol. 9131 (SPIE, Bellingham, WA 2014), 913107.
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Design and optimization of compact freeform lens array for laser beam splitting SPIE 9131 6 2014
- 1. 1 Design and optimization of compact freeform lens array for laser beam splitting Milan Maksimovic Focal -Vision and Optics, Enschede, The Netherlands Brussels, Belgium, 14 - 17 April 2014
- 2. 2 Outline • Introduction: free-form optics and beam shaping • Motivation: laser beam multiplexing • Design Method • Design Examples: simulations results and analysis • Concluding remarks
- 3. 3 Introduction • Freeform optics: no rotational invariance, surfaces with arbitrary shape and regular or irregular global or local structure: • enhanced flexibility in design, • boost in optical performances, • combining multiplefunctionalities into single component, • simplifying complex optical systems by reducing element count, • lowering costs in manufacturing, • reducing stray-light • easing system integration and assembly • Laser beam shaping (splitting) to achieve parallelism • Lens array archives this purpose by the geometrical aperture splitting using the pupil division by individual lenslets residing within sub-apertures • Other optical elements are used and needed to obtain functions such as beam focusing, combining or collimating
- 4. 4 Motivation: design of 1x laser diode to 3x fibers coupler • High-power LD (elliptical) beam splitting into 3 fibers with equalized energy per channel • System components: Individual lenses • Collimatorlens • Single focusing lens element per spot • Manufacturing cost high (number of components) • Assembly tolerances (for many elements) are critical
- 5. 5 Element representation: • Low order aspheric + specific aperture on input • Low order aspheric lenslet in the focusing lens array Design and optimization (using standard software packageZemax): • Custom merit function using real ray coordinates: explicit specification of in-out relationship per each channel (spot) • Pupil sampling (grid) define sampling rays f0r merit function • Multi-parameter optimization • Local optimizer (DLS or OD): -> Initial starting point critical ! • Free-form surface representation: 2 2 2 2 2 ( ) ( , ) , 1 1 ( ) i i i c x y z x y w x y Kc x y where c=1/R is base curvature, K is base conic constant, wi is weight in expansion and Φ is suitable basis function in expansion Compact beam splitter: design method
- 6. 6 Compact beam splitter: design method Compact beam splitter with regular lens array: 1x3 (left) and 1x 5 (right) Optical layouts for: collimator (left), single lenslet (center) and 1x3 lens array (right). Fixed input parameters (example): • Object and image distance : 50mm • Entrance pupil diameter: 30mm • Rectangular aperture of 10x30 mm • Lens array 10x10 mm, (replicated in vertical direction) Merit Function based on real ray position @ image plane! Pupil sampling grid defines input ray position sampling !
- 7. 7 Different pupil sampling grids used to compute merit function Fibonacci sampling grid: • Deterministic algorithm based on Fibonacci spiral • Uniform and isotropic resolution • Equal area (contribution) per each grid point
- 8. 8 Compact design of 1x3 beam splitter using regular lens array Composite Fibonacci pupil sampling grid used in merit function , layout with rays generated in the merit function, 3D model and multi-spot surface plot in the image pane (left to right respectively).
- 9. 9 Compact design of 1x3 beam splitter using regular lens array Surface sag map (left) and cross-section (right) of lens array surface Optimization with radius and conic as variables : -> R=-22.9954mm and K=-2.1314
- 10. 10 Compact beam splitter design using general freeform surface Extended Polynomial surface representation Surface sag map (left) and sag cross-section (right) (Extended Polynomial surface after the optimization with 150 variables) 2 2 2 2 2 , ( ) ( , ) 1 1 ( ) m n mn m n c x y z x y c x y Kc x y
- 11. 11 Compact beam splitter design using general freeform surface Merit function vs. number of variables used in optimization with different size of pupil sampling grids: 0 50 100 150 0.5 1 1.5 2 2.5 3 Number ofVariables MeritFunction Extended Polynomial Representation 17 points per segment 51 points per segment 153 points pr segment
- 12. 12 Compact beam splitter design using general freeform surface Zernike surface representation : Surface sag map (left) and sag cross-section (right) of Zernike surface after the optimization with 37 variables 2 2 2 2 2 2 1...8 1..37 ( ) ( , ) ( , ) 1 1 ( ) i i j j i j c x y z x y r A Z Kc x y
- 13. 13 Compact beam splitter design using irregular lens array Motivation/ Application: different power ratio per spot! Beam splitter 1x3 design with irregular lens array: layout (left) and 3D model (right) Surface intensity plot in the entrance pupil (left) and multi-spot surface intensity plot in the image plane (right)
- 14. 14 Compact beam splitter design using irregular lens array: smoothing using image processing technique Surface sag map of irregular lens array after smoothing Sharp transitions removal: Gaussian filter followed by Median filter in the transition region (local smoothing!)
- 15. 15 Compact beam splitter design using irregular lens array: CAD model smoothing CAD model post-processing • heuristic approach • CAD surface representation often implies less accurate ray tracing! • Iterative procedure: (Zemax->CAD->Zemax) Example of successful design iteration:
- 16. 16 Concluding remarks • We demonstrated feasibility of freeform design of compact beam splitting element that combines both functions of collimation and beam splitting into one (both regular and irregular structure is possible) • Design relaying on multi-parameter optimization + custom design merit function based on real ray coordinates at target location works, but: • Standard free-form surfaces often fail to produce design directly and with small number of variables-> inefficient design process! • Open questions: optimal free-form representation • Pupil sampling method based on Fibonacci grid (highly structured grid and having features usually associated with random grids) improves convergence in local optimization procedure • Designs often require post-processing for manufacturing constraints (smoothing) • Application of local filtering techniques borrowed from image processing produce smoothed versions of surfaces with discontinuities • Possible applications of similar designs are in laser fiber coupling and off-axis multi-spot generation where power splitting ratio can be arbitrarily predefined.
- 17. 17 Thank you for the attention!