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Einrichtungen >> Technische Fakultät (TF) >> Verwaltung und Serviceeinrichtungen Technische Fakultät >> MAOT - Master Programme in Advanced Optical Technologies (Elitestudiengang) >>
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Geschäftsstelle MAOT
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Advanced Laser -
- Dozent/in:
- Nicolas Joly
- Angaben:
- Vorlesung mit Übung, 4 SWS, Schein, ECTS: 5
- Termine:
- Fr, 12:30 - 16:30, AOT-Kursraum
Einzeltermin am 21.4.2020, 9:00 - 12:00, AOT-Kursraum
- Studienrichtungen / Studienfächer:
- WPF AOT-GL 2-3
- Voraussetzungen / Organisatorisches:
- 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.
- Inhalt:
- 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)
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Computer Vision [CV] -
- Dozentinnen/Dozenten:
- Ronak Kosti, Marc Stamminger, Vincent Christlein
- Angaben:
- Vorlesung, 2 SWS, ECTS: 2,5, nur Fachstudium
- Termine:
- Do, 16:15 - 17:45, 0.68
- Studienrichtungen / Studienfächer:
- WPF INF-MA ab 1
WF ICT-MA-MPS ab 1
WF CME-MA ab 1
- Inhalt:
- This lecture discusses important algorithms from the field of computer vision. The emphasis lies on 3-D vision algorithms, covering the geometric foundations of computer vision, and central algorithms such as stereo vision, structure from motion, optical flow, and 3-D multiview reconstruction. The course will also introduce Convolutional Neural Networks (with some examples to play around) and discuss it's importance and impact. Participants of this advanced course are expected to bring experience from prior lectures either from the field of pattern recognition or from the field of computer graphics.
Due to the unfortunate situation with the coronavirus (as of April 2020), it is not possible to start the course in the traditional face-to-face manner. We start with an 'inverted classroom' approach, where we pre-record lectures and upload them. Students are required to watch them before the actual lecture period. The actual lecture period (over Zoom) is dedicated to solving doubts and answering queries that students might have for the lectures watched.
- Empfohlene Literatur:
- Richard Szeliski: Computer Vision: Algorithms and Applications, Springer 2011.
Richard Hartley and Andrew Zisserman: Multiple view geometry in Computer Vision. Cambridge university press, 2003.
- Schlagwörter:
- computer vision; stereo vision; structure from motion; multi-view reconstruction; convolutional neural networks
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Deep Learning [DL] -
- Dozentinnen/Dozenten:
- Andreas Maier, Katharina Breininger
- Angaben:
- Vorlesung, 2 SWS, ECTS: 2,5, nur Fachstudium, Information regarding the online teaching will be added to the studon course
- Termine:
- Mo, 14:15 - 15:45, H4
- Studienrichtungen / Studienfächer:
- WPF INF-MA ab 1
WPF MT-MA-BDV 1
- Voraussetzungen / Organisatorisches:
- The following lectures are recommended:
Application via https://www.studon.fau.de/crs2898025.html
- Inhalt:
- Deep Learning (DL) has attracted much interest in a wide range of applications such as image recognition, speech recognition and artificial intelligence, both from academia and industry.
This lecture introduces the core elements of neural networks and deep learning, it comprises:
(multilayer) perceptron, backpropagation, fully connected neural networks
loss functions and optimization strategies
convolutional neural networks (CNNs)
activation functions
regularization strategies
common practices for training and evaluating neural networks
visualization of networks and results
common architectures, such as LeNet, Alexnet, VGG, GoogleNet
recurrent neural networks (RNN, TBPTT, LSTM, GRU)
deep reinforcement learning
unsupervised learning (autoencoder, RBM, DBM, VAE)
generative adversarial networks (GANs)
weakly supervised learning
applications of deep learning (segmentation, object detection, speech recognition, ...)
The accompanying exercises will provide a deeper understanding of the workings and architecture of neural networks.
- Empfohlene Literatur:
- Ian Goodfellow, Yoshua Bengio, Aaron Courville: Deep Learning. MIT Press, 2016
Christopher Bishop: Pattern Recognition and Machine Learning, Springer Verlag, Heidelberg, 2006
Yann LeCun, Yoshua Bengio, Geoffrey Hinton: Deep learning. Nature 521, 436–444 (28 May 2015)
- Schlagwörter:
- deep learning; machine learning
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Deep Learning Exercises [DL E] -
- Dozentinnen/Dozenten:
- Katharina Breininger, Sulaiman Vesal, Florian Thamm, Felix Denzinger, Hendrik Schröter
- Angaben:
- Übung, 2 SWS, ECTS: 2,5, nur Fachstudium, This course will be held online until the coronavirus pandemic is contained to such an extent that the Bavarian state government can allow face-to-face teaching again. Information regarding the online teaching will be added to the studon course
- Studienrichtungen / Studienfächer:
- WPF INF-MA ab 1
- Schlagwörter:
- deep learning; machine learning
| | | Mo | 12:00 - 14:00 | 0.01-142 CIP | |
Breininger, K. Vesal, S. Schröter, H. | |
| | Di | 18:00 - 20:00 | 0.01-142 CIP | |
Breininger, K. Vesal, S. Schröter, H. | |
| | Mi | 16:00 - 18:00 | 0.01-142 CIP | |
Breininger, K. Vesal, S. Schröter, H. | |
| | Do | 14:00 - 16:00 | 0.01-142 CIP | |
Breininger, K. Vesal, S. Schröter, H. | |
| | Fr | 8:00 - 10:00 | 0.01-142 CIP | |
Breininger, K. Vesal, S. Schröter, H. | |
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Engineering of Solid State Lasers [ENGSSL] -
- Dozentinnen/Dozenten:
- Martin Hohmann, Christoph Pflaum, Kristian Cvecek, Tobias Staudt
- Angaben:
- Vorlesung, 2 SWS, benoteter Schein, ECTS: 2,5, Weitere Infos / Further Informations in "Organisatorisches"
- Termine:
- Mi, 14:15 - 15:45, SR LPT 02.030
- Studienrichtungen / Studienfächer:
- WPF IP-BA 5-6
WPF MB-MA-IP 2
- Voraussetzungen / Organisatorisches:
- Ob der derzeitigen Situation wird diese Vorlesung vorerst in digitaler Form stattfinden - als Zoom-Webinar zum regulären Vorlesungszeitpunkt. Weitere Infos über den Fortgang finden Sie in der entsprechenden StudOn-Gruppe. Den Link zur StudOn-Gruppe finden Sie weiter unten.
Due to the current situation, this lecture will be tought in a digital manner for the time being - as a Zoom webinar at the scheduled time of the lecture. We will post further information on that in the corresponding StudOn group. The link to the StudOn group can be found in the following.
- Inhalt:
- The targeted audience is master level students who are interested in expanding their theoretical and practical knowledge in the field of solid state laser engineering. We recommend basic knowledge in optics.
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Leuchtstoffe / Phosphors -
- Dozentinnen/Dozenten:
- Miroslaw Batentschuk, Albrecht Winnacker
- Angaben:
- Vorlesung, 2 SWS, benoteter Schein, ECTS: 3, nur Fachstudium, VL findet über ZOOM statt. Zugangsdaten werden im studOn jede Woche hochgeladen.Anmeldung im StudOn ist erforderlich.
- Termine:
- Mo, 14:15 - 15:45, Raum n.V.
Vorbesprechung per live-ZOOM-Übertragung. Für alle VL, Seminare, Praktika etc. Findet als live-ZOOM-Übertragung statt. Registrieren Sie sich bitte für das entsprechnde Datum und die Uhrzeit: https://fau.zoom.us/meeting/register/tJUpce2trD0rGNzOM9GyJCKXI8iU5vxIUPFN . Nach der Registrierung erhalten Sie eine Bestätigungs-E-Mail mit Informationen über die Teilnahme am Meeting.
ab 11.5.2020
Vorbesprechung: Dienstag, 21.4.2020, 14:00 - 15:00 Uhr
- Studienrichtungen / Studienfächer:
- PF MWT-MA-WET 2
WPF MWT-MA-WET 2
WPF NT-MA 2
WPF AOT-GL 2
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Light Scattering: Lecture [OM/LS] -
- Dozentinnen/Dozenten:
- Andreas Paul Fröba, Michael Rausch
- Angaben:
- Vorlesung, 2 SWS, ECTS: 5, This lecture and the corresponding exercise are offered online via Zoom at the times stated in UnivIS as long as on-site attendence is not possible due to the Corona pandemic. First lecture is on Monday, April 20, 2020 at 18:15. For attending the lectures and the corresponding exercises, registration for the StudOn-course "Light Scattering" until April 19, 2020 at 12:00 a.m. is mandatory (https://www.studon.fau.de/crs2182923-join.html).
- Termine:
- Mo, 18:15 - 19:45, AOT-Kursraum
First lecture is on Monday, April 20, 2020 at 18:15.
ab 23.4.2020
- Studienrichtungen / Studienfächer:
- WPF AOT-GL 2-3
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Machine Learning for Physicists -
- Dozent/in:
- Florian Marquardt
- Angaben:
- Vorlesung, 2 SWS, ECTS: 5, nur Fachstudium, die Vorlesung wird aufgrund der aktuellen Situation als "inverted classroom" angeboten, siehe zusätzliche Informationen - Due to the current situation, this lecture is moved to an "inverted classroom" format; see additional information; registration required: please follow zoom registration link on https://machine-learning-for-physicists.org
- Termine:
- Mi, 17:00 - 19:00, Raum n.V.
- Studienrichtungen / Studienfächer:
- WF Ph-BA ab 5
WF Ph-MA ab 1
WF PhM-BA ab 5
WF PhM-MA ab 1
- Voraussetzungen / Organisatorisches:
- This is a course introducing modern techniques of machine learning, especially deep neural networks, to an audience of physicists. Neural networks can be trained to perform diverse challenging tasks, including image recognition and natural language processing, just by training them on many examples. Neural networks have recently achieved spectacular successes, with their performance often surpassing humans. They are now also being considered more and more for applications in physics, ranging from predictions of material properties to analyzing phase transitions. We will cover the basics of neural networks, convolutional networks, autoencoders, restricted Boltzmann machines, and recurrent neural networks, as well as the recently emerging applications in physics. Prerequisites: almost none, except for matrix multiplication and the chain rule.
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Medical Image Processing for Diagnostic Applications (VHB-Kurs) [MIPDA] -
- Dozentinnen/Dozenten:
- Julian Hoßbach, Tristan Gottschalk, Lina Felsner
- Angaben:
- Vorlesung, 4 SWS, ECTS: 5
- Termine:
- Zeit/Ort n.V.
- Studienrichtungen / Studienfächer:
- WPF INF-MA ab 1
WPF INF-BA-V-ME ab 5
PF CE-MA-TA-IT ab 1
WPF IuK-MA-MMS-INF ab 1
WPF ICT-MA-MPS 1-4
WPF MT-MA-BDV ab 1
WPF MT-BA ab 5
WF CME-MA 1-4
- Voraussetzungen / Organisatorisches:
- Requirements: mathematics for engineering
Organization:
This is an online course of Virtuelle Hochschule Bayern (VHB).
Go to https://www.vhb.org to register to this course.
FAU students register for the written exam via meinCampus.
- Inhalt:
- Medical imaging helps physicians to take a view inside the human body and therefore allows better treatment and earlier diagnosis of serious diseases.
However, as straightforward as the idea itself is, so diversified are the technical difficulties to overcome when implementing a clinically useful imaging device. We begin this course by discussing all available modalities and the actual imaging goals which highly affect the imaging result. Some modalities produce very noisy results, but there are multiple other artifacts that show up in raw acquisition data and have to be dealt with. We address these issues in the chapter preprocessing and show how to compensate for image distortions, how to interpolate defect pixels, and finally correct bias fields in magnetic resonance images. The largest portion of this course covers the theory of medical image reconstruction. Here, from a set of projections from different viewing angles a 3-D image is merged that allows a definite localization of anatomical and pathological features. Following roughly the historical development of CT devices, we study the process from parallel beam to fan beam geometry and include a discussion of phantoms as a tool for calibration and image quality assessment. We then move forward and learn about reconstruction in 3-D. Since the system matrix often grows in dimensions such that many direct solvers become infeasible, we also discuss pros and cons of iterative methods. In the final chapter, image registration is introduced as the concept of computing the mapping that maps the content of one image to another. Two different acquisitions usually result in images that are at least rotated and translated against each other. Image registration forms the set of tools that we need to match certain image features in order to align both images for further processing, image improvement or image overlays.
- Schlagwörter:
- Mustererkennung, Medizinische Bildverarbeitung
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Pattern Analysis [PA] -
- Dozent/in:
- Christian Riess
- Angaben:
- Vorlesung, 3 SWS, benoteter Schein, ECTS: 3,75, This course will be held online until the coronavirus pandemic is contained to such an extent that the Bavarian state government can allow face-to-face teaching again
- Termine:
- Mi, 14:15 - 15:45, H16
Do, 16:15 - 17:45, H16
- Studienrichtungen / Studienfächer:
- PF MT-MA-BDV 1-4
WPF IuK-MA-MMS-INF 1-4
WPF ICT-MA-MPS 1-4
WPF CME-MA 1-4
WF CME-MA 1-4
WPF INF-MA 1-4
WPF CE-MA-INF ab 1
WF ASC-MA 1-4
- Voraussetzungen / Organisatorisches:
- Please join the class "Pattern Analysis" in studOn. All lecture material will be linked and made available there.
It is recommended (but not mandatory) that participants attend the lecture Pattern Recognition first.
- Inhalt:
- This lecture complements the lectures "Introduction to Pattern Recognition" and "Pattern Recognition".
In this third edition, we focus on analyzing and simplifying feature representations.
Major topics of this lecture are density estimation, clustering, manifold learning, hidden Markov models, conditional random fields, and random forests.
The lecture is accompanied by exercises, where theoretical results are
practically implemented and applied.
- Empfohlene Literatur:
- Christopher Bishop: Pattern Recognition and Machine Learning, Springer Verlag, Heidelberg, 2006
T. Hastie, R. Tibshirani, J. Friedman: The Elements of Statistical Learning, 2nd edition, Springer Verlag, 2017.
Antonio Criminisi and J. Shotton: Decision Forests for Computer Vision and Medical Image Analysis, Springer, 2013
papers referenced in the lecture
- Schlagwörter:
- pattern recognition, pattern analysis
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Seminar on Solar Energy [SolSem] -
- Dozentinnen/Dozenten:
- Christoph J. Brabec, Jens Hauch
- Angaben:
- Seminar, 2 SWS, benoteter Schein, ECTS: 2, nur Fachstudium, findet aus aktuellem Anlass mittels Zoom-Live-Übertragung statt. Anmeldung im StudOn ist erforderlich. Zugangsdaten zu ZOOM werden über StudOn mitgeteilt, auch für die Vorbesprechung.
- Termine:
- erster Termin 28.04.2020, 15:00 Uhr
Vorbesprechung: Dienstag, 21.4.2020, 14:00 - 15:00 Uhr
- Studienrichtungen / Studienfächer:
- WF CE-BA-SEM ab 5
WF ET-BA ab 5
PF AOT-GL 1
WF AOT-GL ab 1
WF ET-MA-MWT ab 1
WF CE-MA-SEM ab 1
WF INF-MA ab 1
WF MWT-MA-WET ab 1
WF NT-MA ab 1
- Schlagwörter:
- Solar Energy Seminar
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Simulation Methods in Optics -
- Dozentinnen/Dozenten:
- Norbert Lindlein, Nicolas Joly
- Angaben:
- Vorlesung mit Übung, 4 SWS, ECTS: 5
- Termine:
- Mo, 14:00 - 17:30, AOT-Kursraum
- Studienrichtungen / Studienfächer:
- WF Ph-BA ab 6
WF Ph-MA ab 1
WF LaP-SE ab 6
WF CE-BA-TW 6
WF AOT-GL ab 2
- Inhalt:
- 1. Ray tracing: Principle and applications
2. Aberrations: which type of aberrations exist, how do they depend on the numerical aperture and the field angle
3. Diffraction and free space propagation by the angular spectrum of plane waves
4. Debye integral in scalar optics
5. Wave-optical scalar simulation methods: thin element approximation, BPM (mostly the simple paraxial one), WPM, some comments to numerical implementation
6. Waveguide theory (mode solver and evaluation of dispersion for various type of waveguides: step-index fibre, hollow-core PCF, filled with gas…)
7. Nonlinear propagation of pulses in fibre (typically, the resolution of the nonlinear Schrödinger equation so as to study the theory of integration and the split-step method)
8. Gaussian beam and ABCD matrices. (Object oriented programming)
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