Jan David Fischbach, Fridtjof Betz, Nigar Asadova, Pietro Tassan, Darius Urbonas, Thilo Stöferle, Rainer F. Mahrt, Sven Burger, Carsten Rockstuhl, Felix Binkowski, Thomas Jebb Sturges
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A framework to compute resonances arising from multiple scattering
A sample refinement strategy suitable for accurately locating a large number
of poles is introduced. We tie the AAA algorithm into an automatic
differentiation framework to efficiently differentiate multi-scattering
resonance calculations. The resulting resonance solver allows for efficient
gradient-based optimization, demonstrated here by the inverse design of an
integrated exciton-polariton cavity. This contribution serves as an important
step towards efficient resonance calculations in a variety of multi-scattering
scenarios, such as inclusions in stratified media, periodic lattices, and
scatterers with arbitrary shapes. A sample refinement strategy suitable for
accurately locating a large number of poles is introduced. We tie the AAA
algorithm into an automatic differentiation framework to efficiently
differentiate multi-scattering resonance calculations. The resulting resonance
solver allows for efficient gradient-based optimization, demonstrated here by
the inverse design of an integrated exciton-polariton cavity. This contribution
serves as an important step towards efficient resonance calculations in a
variety of multi-scattering scenarios, such as inclusions in stratified media,
periodic lattices, and scatterers with arbitrary shapes.
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