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Labcourse: Optical Material and Systems [OMS/LAB] Lecturers: Nicolas Joly, Angela Perez Castaneda Details: Praktikum, 2 cred.h, certificate, ECTS: 2,5, nur Fachstudium Dates: block seminar 13.6.2022-27.6.2022 Mon, block seminar 23.6.2022-14.7.2022 Thu, 9:00 - 17:00, AOT-Praktikumslabor Students for whom the course is mandatory will be informed about the details by the MAOT office. Preliminary meeting: Monday, 23.5.2022, 10:15 - 11:45 Uhr, AOT-Kursraum Fields of study: WPF AOT-GL ab 2

	Exercises in Computational Optics CE & MAOT Lecturer: Phillip Rall Details: Übung, 2 cred.h, graded certificate, nur Fachstudium, für FAU Scientia Gaststudierende zugelassen, Room: 00.133-128 (Animationslabor) Fields of study: WPF AOT-GL ab 1
		Tue	12:15 - 13:45	Übung 3 / 01.252-128		Rall, Ph.
	Room: 00.133-128 (Animationslabor)
		Wed	12:15 - 13:45	Übung 3 / 01.252-128		Rall, Ph.
	Room: 00.133-128 (Animationslabor)

Advanced nonlinear optics Lecturers: Nicolas Joly, Hanieh Fattahi, Maria Chekhova Details: Vorlesung, 2 cred.h, ECTS: 5, nur Fachstudium Dates: Wed, 14:00 - 16:00, HE Fields of study: WPF AOT-GL 1 Contents: The goal of this lecture is to explore advanced concepts of nonlinear optics and their applications. This will cover the following topics: Nonlinear propagation in solid-core photonic crystal fibres (modulation instability, four-wave mixing, soliton dynamics, supercontinuum generation) and in hollow-core photonic crystal fibres (generation of tunable dispersive waves, plasma in fibres) Nonlinear optical effects (parametric down-conversion, four-wave mixing, modulation instability) for the generation of nonclassical light (entangled photons, squeezed light, twin beams, heralded single photons). Nonlinear effects for generating high energy sub cycle pulses (kerr-lens mode-locking, Yb:YAG laser technology, optical parametric amplification, pulses synthesis, attosecond pulse generation) Keywords: Please register using StudOn (https://www.studon.fau.de/crs3671904_join.html)

Fundamentals in Anatomy and Physiology for Engineers [Anatomy & Physiology] Lecturers: Benedikt Kleinsasser, Friedrich Paulsen Details: Vorlesung, 4 cred.h, für Anfänger geeignet, nur Fachstudium Dates: to be determined Fields of study: WPF AOT-GL ab 1

	Laser Tissue Interaction [LTI] Lecturer: Florian Klämpfl Details: Vorlesung, 2 cred.h, ECTS: 2,5, für FAU Scientia Gaststudierende zugelassen, Weitere Infos / Further Informations in "Organisatorisches" Fields of study: WPF AOT-GL 2 Contents: The exercises for Laser Tissue Interaction are mandatory for this lecture!
		Tue	14:15 - 15:45	SR LPT 02.030		Klämpfl, F.

Laser Tissue Interaction Exercises [LTI-E] Lecturers: Florian Klämpfl, Moritz Späth, Martin Hohmann, Dongqin Ni Details: Übung, 2 cred.h, ECTS: 2,5, für FAU Scientia Gaststudierende zugelassen, Weitere Infos / Further Informations in "Organisatorisches" Dates: Fri, 10:15 - 11:45, SR LPT 02.030 Fields of study: WPF AOT-GL 2

Linear and non-linear fibre optics [LinNLFO] Lecturer: Bernhard Schmauss Details: Vorlesung, 2 cred.h, certificate, ECTS: 5, nur Fachstudium, für FAU Scientia Gaststudierende zugelassen Dates: Thu, 14:15 - 15:45, HF-Technik: SR 05.222 Fields of study: WPF AOT-GL ab 2

Linear and non-linear fibre optics: Exercise [LinNLFO Ex] Lecturer: Lisa Härteis Details: Übung, 2 cred.h, für FAU Scientia Gaststudierende zugelassen Dates: Mon, 10:15 - 11:45, HF-Technik: SR 05.222 Attention: First Exercise on May 2nd! Fields of study: WPF AOT-GL ab 2

Advanced Laser Lecturer: Nicolas Joly Details: Vorlesung mit Übung, 4 cred.h, certificate, ECTS: 5, für FAU Scientia Gaststudierende zugelassen Dates: Fri, 12:30 - 16:30, AOT-Kursraum First meeting: 6 May 2022 starting 6.5.2022 Fields of study: WPF AOT-GL 2-3 Prerequisites / Organisational information: Due to the corona virus situation the courses will be conducted as an e-learning course. Please go to the StudOn-link provided below for more information. Contents: Z-cavity Dispersion management for ultra-short pulse generation Various technique of characterisation of ultra-short pulses Polarisation effects and Jones’ formalism Semi-classical model for a laser (Maxwell-Bloch equations) The rest of the lecture will consist of seminar presented by the students on the topics of their choice. These topics should cover a particular aspect (fundamental, theoretical, applied) of a laser system or an application of laser (e.g. optical tweezer, high-precision metrology, high-resolution spectroscopy… etc)

Computational Optics CE & MAOT [CompOptCE+MAOT] Lecturer: Christoph Pflaum Details: Vorlesung mit Übung, 2 cred.h, ECTS: 7,5, für FAU Scientia Gaststudierende zugelassen Dates: Wed, 8:15 - 9:45, 01.151-128 Fields of study: WPF AOT-GL ab 1

Lab Course in Thermophysical Properties of Working Materials in Process and Energy Engineering [TPE-PR] Lecturers: Thomas Koller, Michael Rausch, Andreas Paul Fröba, Tobias Klein Details: Praktikum, 3 cred.h, certificate, ECTS: 2,5, für FAU Scientia Gaststudierende zugelassen, Registration is possible within the first lecture in "Vorlesung und Übung in Thermophysikalische Eigenschaften von Arbeitsstoffen der Verfahrens- und Energietechnik". Dates: Thu, 16:15 - 18:30, AOT-Kursraum Fields of study: WF AOT-GL ab 1 Prerequisites / Organisational information: Vorlesung und Übung in Thermophysikalische Eigenschaften von Arbeitsstoffen der Verfahrens- und Energietechnik

Optical Lithography: Technology, Physical Effects, and Modelling [HLT IV - LITHO-V] Lecturer: Andreas Erdmann Details: Vorlesung, 2 cred.h, für FAU Scientia Gaststudierende zugelassen Dates: Thu, 14:15 - 15:45, 0.111 Fields of study: WF AOT-GL ab 1 Contents: Semiconductor lithography covers the process of pattern transfer from a mask/layout to a photosensitive layer on the surface of a wafer. It is one of the most critical steps in the fabrication of microelectronic circuits. The majority of semiconductor chips are fabricated by optical projection lithography. Other lithographic techniques are used to fabricate lithographic masks or new optical and mechanical devices on the micro- or nanometer scale. Innovations such as the introduction of optical proximity correction OPC), phase shift masks (PSM), special illumination techniques, chemical amplified resist (CAR) materials, immersion techniques have pushed the smallest feature sizes, which are produced by optical projection techniques, from several wavelengths in the early 80ties to less than a quarter of a wavelength nowadays. This course reviews different types of optical lithographies and compares them to other methods. The advantages, disadvantages, and limitations of lithographic methods are discussed from different perspectives. Important components of lithographic systems, such as masks, projection systems, and photoresist will be described in detail. Physical and chemical effects such as the light diffraction from small features on advanced photomasks, image formation in high numerical aperture systems, and coupled kinetic/diffusion processes in modern chemical amplified resists will be analysed. The course includes an in-depth introduction to lithography simulation which is used to devise and optimize modern lithographic processes.

Übung zu Halbleitertechnologie IV - Optical Lithography [HLT IV - LITHO-Ü] Lecturer: Andreas Erdmann Details: Übung, 2 cred.h, für FAU Scientia Gaststudierende zugelassen, Für Master AOT verpflichtende Zusatzveranstaltung, für andere Studiengänge freiwillig Dates: Thu, 12:15 - 13:45, 0.111 Fields of study: WF AOT-GL ab 1

Optimization for Engineers [OptEngLec] Lecturer: Johannes Hild Details: Vorlesung mit Übung, 3 cred.h, ECTS: 5 Dates: Mon, 12:15 - 13:45, H16 Tue, 14:15 - 15:45, H16 See StudOn Fields of study: WF AOT-GL ab 1 Prerequisites / Organisational information: This course aims at students of the Faculty of Engineering of all disciplines and is suitable as an elective subject in the Bachelor's and Master's degree. Requires contents of the lecture Mathematics for Engineers I, II and III. Especially: Linear algebra Analysis of real valued functions Differential and integral calculus in multi dimensional spaces Programming homeworks require basic knowledge in the implementation of algorithms and data structures in a development environment. Contents: Introduction to continuous optimization problems and methods with and without constraints Classification of problem types Optimality conditions and termination criterions Descent directions and line search methods Convergence analysis Unconstrained optimization Steepest descent and conjugate gradient Newton-type methods Nonlinear Least Squares Constrained optimization Projection methods Trust Region Barrier and penalty methods Outlook Linear programming and simplex method Integer programming Noisy functions Programming Homeworks Get in touch with GNU Octave Implementation of optimization algorithms Algorithmic optimization of test problems Recommended literature: Nocedal, Jorge and Wright, Stephen J.: Numerical Optimization. Springer Serie in Operations Research, 2006. Kelley, C. T.: Iterative Methods for Optimization. Frontiers in Applied Mathematics 18, SIAM Philadelphia 1999; Polak, E.: Optimization. Algorithms and Consistent Approximations.Applied Mathematical Sciences, Volume 124, Springer-Verlag New York, 1997. Jarre, F.:Optimierung, Springer 2003; Hamacher, H.W. and K. Klamroth, K.:Linear and Network Optimization: bilingual textbook. Vieweg 2000 Keywords: optimierung optimization

Thermophysical Properties of Working Materials in Process and Energy Engineering [TPE] Lecturers: Thomas Koller, Andreas Paul Fröba, Michael Rausch, Tobias Klein Details: Vorlesung mit Übung, 4 cred.h, ECTS: 5, für FAU Scientia Gaststudierende zugelassen Dates: Tue, Wed, 08:15 - 09:45, AOT-Kursraum Fields of study: WF AOT-GL ab 1