Freeform optics design for extended sources in paraxial approximation exploiting the expectation maximization algorithm

Völl, Annika; Berens, Michael; Wester, Rolf; Buske, Paul; Stollenwerk, Jochen; Loosen, Peter

doi:10.1364/oe.412541

Cited by 10 publications

(4 citation statements)

References 23 publications

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“…The design algorithm is based on the solution of the so called Monge-Ampère equation and a following flux optimization step [17]. Additionally, we have developed methods which account for finite divergence angles that are based on phase space considerations [18] or utilize the expectation maximization from statistics [19].…”

Section: Freeform Opticsmentioning

confidence: 99%

Application-adapted beam shaping with cutting-edge optical elements in laser materials processing

Völl

Buske

Stollenwerk

et al. 2023

High-Power Laser Materials Processing: Applications, Diagnostics, and Systems XII

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The quality, efficiency and robustness of laser materials processing significantly benefits from an application-adapted beam shaping. For a successful realization of tailored beam shapes that utilizes state-of-the-art optic concepts, research in two different steps is necessary. First, information about the required beam shape (especially in terms of intensity distribution) is needed. During the last years, we have developed and validated a method to solve the so-called inverse heat conduction problem which enables the derivation of an intensity distribution that specifically tailors the induced temperature profile within the processed material. Here, we present the latest enhancement of the algorithm to complex time-dependent scenarios and new applications, e.g. from the field of surface treatment and tape placement. With the knowledge of the target beam shape, in a second step, optical systems must be designed that enable the realization of the achieved, highly complex intensity distributions. We further demonstrate the potential and limits of novel optics such as freeform mirrors, LCoS-SLMs or diffractive neural networks as well as VCSELs for application-adapted beam shaping. We especially present specific design methods that can contribute to a robust, flexible, and practical realization in various applications.

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Section: Freeform Opticsmentioning

confidence: 99%

Application-adapted beam shaping with cutting-edge optical elements in laser materials processing

Völl

Buske

Stollenwerk

et al. 2023

High-Power Laser Materials Processing: Applications, Diagnostics, and Systems XII

Self Cite

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“…For extended light sources, freeform surfaces have been designed for uniform illumination via edge ray mapping 29 and for specific irradiance distributions via expectation maximization algorithm. 30 Most white LEDs are Lambertian emitters with an intensity distribution that reduces to 50% at 60 deg from the surface normal. To capture all of the rays emitted by a white LED using a reflector, the reflector may need to become undesirably large.…”

Section: Concept Optical Designmentioning

confidence: 99%

“…LEDs are extended sources as compared to ideal point sources and that adds an extra level of challenge for the optical engineers. For extended light sources, freeform surfaces have been designed for uniform illumination via edge ray mapping 29 and for specific irradiance distributions via expectation maximization algorithm 30 . Most white LEDs are Lambertian emitters with an intensity distribution that reduces to 50% at 60 deg from the surface normal.…”

Section: Concept Optical Designmentioning

confidence: 99%

Folded light source: a technique for compact and efficient automotive lighting

Moore,

Alisafaee

2023

Opt. Eng.

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Segmented reflectors are frequently used in automotive lighting applications. Extended light sources are one of the limiting factors on the compactness of segmented reflectors. We propose the technique of folding the light source for achieving highly compact reflector designs while improving their efficiency. We then use the macrofocal approach to design legal low-beam reflectors based on the proposed folded light source technique. We show that our method can deliver 51.2% more optical flux, which results in a significant improvement in the efficiency equal to 26.2%. This technique would allow optical engineers to design more compact and energy-efficient products for automotive headlamps and for general lighting applications.

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“…3 For a compact design, the size of the light source cannot be ignored. Some methods have been proposed for tailoring the irradiance distributions of extended sources, including the over compensation methods, [4][5][6][7] the simultaneous multiple surface (SMS)-based methods, 8,9 the deconvolution methods, [10][11][12][13][14] the parametric optimization methods, [15][16][17][18][19] the edge ray mapping method, 20 the expectation maximization algorithm applied for pinhole image arrangement 21 and the energy accumulating optimization method. 22 Among these methods, the parametric optimization methods are easy to implement and have strong universality.…”

Section: Introductionmentioning

confidence: 99%

Spherical-freeform lens design for uniform illumination based on differentiable ray tracing with uv polynomials

Li,

Tang,

Feng

et al. 2023

Optical Design and Testing XIII

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Freeform optics design for extended sources in paraxial approximation exploiting the expectation maximization algorithm

Cited by 10 publications

References 23 publications

Application-adapted beam shaping with cutting-edge optical elements in laser materials processing

Application-adapted beam shaping with cutting-edge optical elements in laser materials processing

Folded light source: a technique for compact and efficient automotive lighting

Spherical-freeform lens design for uniform illumination based on differentiable ray tracing with uv polynomials

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