Computational Illumination Optics at TU/e

PhD

	Carmela Filosa, Phase space ray tracing for illumination optics
	Bart van Lith, Principles of computational illumination optics
	Corien Prins, Inverse methods for illumination optics
	Lotte Romijn, Generated Jacobian equations in freeform optical design: Mathematical theory and numerics
	Nitin Yadav, Monge-Ampère problems with non-quadratic cost function: Application to freeform optics

Master

• René Beltman
  Solving the Monge-Ampère Equation for a free-form reflector in arbitrary coordinate systems
• Maikel Bertens
  Least-squares method for the Monge-Ampère equation with application to calculating lens surfaces in optical systems
• Siyuan Jiang
  Inverse design of cylindrically symmetric reflector with scattering surfaces
• Jorg Portegies
  Fast ray tracing in phase space for optical design
• Jarno van Roosmalen
  The Monge-Ampère equation for optimal mass transport with applications in optical design
• Teun van Roosmalen
  Saddle point construction for aberrations in grazing incidence mirror systems
• Hannah van Susteren
  Mathematical model for a freeform optical system. Point source to point target with two reflectors
• Ellen Vugts
  The hyperbolic Monge-Ampère equation
• Rutger Wessels
  A least-squares algorithm for the Monge-Ampère Equation: analysis and application to freeform optics

Bachelor

• Robert van Barlingen
  An introduction to phase space ray tracing: and everything that came before
• Maikel Bertens
  Numerical models of light scattering in a dusty plasma
• Lotte van de Leur
  Comparing two methods for Monte Carlo ray tracing
• Kevin Menting
  Time integration methods for gradient-index media using Hamiltonian Optics
• Alex van der Plas
  Inverse optical design methods for freeform two-dimensional systems
• Lucas Ronckers
  Approximation of the Luneburg lens with discrete layers using geometric optics
• Jesse Schardijn
  Simulating light propagation by using the Fast Marching Method