@inbook{39428,
  author       = {{Hilleringmann, Ulrich}},
  booktitle    = {{Silizium-Halbleitertechnologie}},
  isbn         = {{9783658234430}},
  publisher    = {{Springer Fachmedien Wiesbaden}},
  title        = {{{Ätztechnik}}},
  doi          = {{10.1007/978-3-658-23444-7_5}},
  year         = {{2018}},
}

@inproceedings{39436,
  author       = {{Becker, Thales E. and Vidor, Fabio F. and Wirth, Gilson I. and Meyers, Thorsten and Reker, Julia and Hilleringmann, Ulrich}},
  booktitle    = {{2018 IEEE 19th Latin-American Test Symposium (LATS)}},
  publisher    = {{IEEE}},
  title        = {{{Time domain electrical characterization in zinc oxide nanoparticle thin-film transistors}}},
  doi          = {{10.1109/latw.2018.8349695}},
  year         = {{2018}},
}

@inproceedings{39437,
  author       = {{Becker, Thales E. and Vidor, Fabio F. and Wirth, Gilson I. and Meyers, Thorsten and Reker, Julia and Hilleringmann, Ulrich}},
  booktitle    = {{2018 IEEE 19th Latin-American Test Symposium (LATS)}},
  publisher    = {{IEEE}},
  title        = {{{Time domain electrical characterization in zinc oxide nanoparticle thin-film transistors}}},
  doi          = {{10.1109/latw.2018.8349695}},
  year         = {{2018}},
}

@inbook{39429,
  author       = {{Hilleringmann, Ulrich}},
  booktitle    = {{Silizium-Halbleitertechnologie}},
  isbn         = {{9783658234430}},
  publisher    = {{Springer Fachmedien Wiesbaden}},
  title        = {{{Oxidation des Siliziums}}},
  doi          = {{10.1007/978-3-658-23444-7_3}},
  year         = {{2018}},
}

@article{39430,
  author       = {{Vollbrecht, Joachim and Oechsle, Peter and Stepen, Arne and Hoffmann, Florian and Paradies, Jan and Meyers, Thorsten and Hilleringmann, Ulrich and Schmidtke, Jürgen and Kitzerow, Heinz}},
  issn         = {{1566-1199}},
  journal      = {{Organic Electronics}},
  keywords     = {{Electrical and Electronic Engineering, Materials Chemistry, Condensed Matter Physics, General Chemistry, Biomaterials, Electronic, Optical and Magnetic Materials}},
  pages        = {{266--275}},
  publisher    = {{Elsevier BV}},
  title        = {{{Liquid crystalline dithienothiophene derivatives for organic electronics}}},
  doi          = {{10.1016/j.orgel.2018.06.002}},
  volume       = {{61}},
  year         = {{2018}},
}

@article{6481,
  author       = {{Durrani, Saad Parvaiz and Balluff, Stefan and Wurzer, Lukas and Krauter, Stefan}},
  issn         = {{2196-5625}},
  journal      = {{Journal of Modern Power Systems and Clean Energy}},
  number       = {{2}},
  pages        = {{255--267}},
  publisher    = {{Springer Nature}},
  title        = {{{Photovoltaic yield prediction using an irradiance forecast model based on multiple neural networks}}},
  doi          = {{10.1007/s40565-018-0393-5}},
  volume       = {{6}},
  year         = {{2018}},
}

@article{6571,
  author       = {{Jurgelucks, Benjamin and Claes, Leander and Walther, Andrea and Henning, Bernd}},
  issn         = {{1055-6788}},
  journal      = {{Optimization Methods and Software}},
  number       = {{4-6}},
  pages        = {{868----888}},
  publisher    = {{Taylor and Francis Ltd.}},
  title        = {{{Optimization of triple-ring electrodes on piezoceramic transducers using algorithmic differentiation}}},
  doi          = {{10.1080/10556788.2018.1435652}},
  volume       = {{33}},
  year         = {{2018}},
}

@inproceedings{29459,
  abstract     = {{Transistor and interconnect wearout is accelerated with transistor scaling resulting in timing variations and consequently reliability challenges in digital circuits. With the emergence of new issues like Electro-migration these problems are getting more crucial. Age monitoring methods can be used to predict and deal with the aging problem. Selecting appropriate locations for placement of aging monitors is an important issue. In this work we propose a procedure for selection of appropriate internal nodes that expose smaller overheads to the circuit, using correlation between nodes and the shareability amongst them. To select internal nodes, we first prune some nodes based on some attributes and thus provide a near-optimal solution that can effectively get a number of internal nodes and consider the effects of electro-migration as well. We have applied our proposed scheme to several processors and ITC benchmarks and have looked at its effectiveness for these circuits.}},
  author       = {{Sadeghi-Kohan, Somayeh and Vafaei, Arash and Navabi, Zainalabedin}},
  booktitle    = {{2018 IEEE 24th International Symposium on On-Line Testing And Robust System Design (IOLTS)}},
  publisher    = {{IEEE}},
  title        = {{{Near-Optimal Node Selection Procedure for Aging Monitor Placement}}},
  doi          = {{10.1109/iolts.2018.8474120}},
  year         = {{2018}},
}

@inproceedings{24187,
  abstract     = {{In this paper, we present a monolithically integrated coherent receiver with on-chip grating couplers, 90° hybrid, photodiodes and transimpedance amplifiers. A transimpedance gain of 7.7 kΩ was achieved by the amplifiers. An opto-electrical 3 dB bandwidth of 34 GHz for in-phase and quadrature channel was measured. A real-time data transmission of 64 GBd-QPSK (128 Gb/s) for a single polarization was performed.}},
  author       = {{Gudyriev, Sergiy and Kress, Christian and Zwickel, Heiner and Kemal, Juned N. and Lischke, Stefan and Zimmermann, Lars and Koos, Christian and Scheytt, Christoph}},
  booktitle    = {{IEEE/OSA Journal of Lightwave Technology}},
  pages        = {{1--1}},
  title        = {{{Coherent ePIC Receiver for 64 GBaud QPSK in 0.25μm Photonic BiCMOS Technology}}},
  doi          = {{10.1109/JLT.2018.2881107}},
  year         = {{2018}},
}

@inproceedings{1588,
  abstract     = {{The exploration of FPGAs as accelerators for scientific simulations has so far mostly been focused on small kernels of methods working on regular data structures, for example in the form of stencil computations for finite difference methods. In computational sciences, often more advanced methods are employed that promise better stability, convergence, locality and scaling. Unstructured meshes are shown to be more effective and more accurate, compared to regular grids, in representing computation domains of various shapes. Using unstructured meshes, the discontinuous Galerkin method preserves the ability to perform explicit local update operations for simulations in the time domain. In this work, we investigate FPGAs as target platform for an implementation of the nodal discontinuous Galerkin method to find time-domain solutions of Maxwell's equations in an unstructured mesh. When maximizing data reuse and fitting constant coefficients into suitably partitioned on-chip memory, high computational intensity allows us to implement and feed wide data paths with hundreds of floating point operators. By decoupling off-chip memory accesses from the computations, high memory bandwidth can be sustained, even for the irregular access pattern required by parts of the application. Using the Intel/Altera OpenCL SDK for FPGAs, we present different implementation variants for different polynomial orders of the method. In different phases of the algorithm, either computational or bandwidth limits of the Arria 10 platform are almost reached, thus outperforming a highly multithreaded CPU implementation by around 2x.}},
  author       = {{Kenter, Tobias and Mahale, Gopinath and Alhaddad, Samer and Grynko, Yevgen and Schmitt, Christian and Afzal, Ayesha and Hannig, Frank and Förstner, Jens and Plessl, Christian}},
  booktitle    = {{Proc. Int. Symp. on Field-Programmable Custom Computing Machines (FCCM)}},
  keywords     = {{tet_topic_hpc}},
  publisher    = {{IEEE}},
  title        = {{{OpenCL-based FPGA Design to Accelerate the Nodal Discontinuous Galerkin Method for Unstructured Meshes}}},
  doi          = {{10.1109/FCCM.2018.00037}},
  year         = {{2018}},
}

@article{57224,
  author       = {{Mujahed, Muhannad and Fischer, Dirk and Mertsching, Bärbel}},
  issn         = {{0921-8890}},
  journal      = {{Robotics and Autonomous Systems}},
  pages        = {{93--110}},
  publisher    = {{Elsevier BV}},
  title        = {{{Admissible gap navigation: A new collision avoidance approach}}},
  doi          = {{10.1016/j.robot.2018.02.008}},
  volume       = {{103}},
  year         = {{2018}},
}

@inproceedings{64371,
  author       = {{Hofmann, Martin R. and Lenz, Marcel and Krug, Robin and Gerhardt, Nils Christopher and Schmieder, Kirsten and Dillmann, Christopher and Welp, Hubert}},
  booktitle    = {{Optical Coherence Tomography and Coherence Domain Optical Methods in Biomedicine XXII}},
  title        = {{{Brain tissue analysis using texture features based on optical coherence tomography images}}},
  doi          = {{10.1117/12.2292032}},
  year         = {{2018}},
}

@inproceedings{64372,
  author       = {{Lenz, Marcel and Krug, Robin and Gerhardt, Nils Christopher and Schmieder, Kirsten and Hofmann, Martin R. and Dillmann, Christopher and Welp, Hubert}},
  booktitle    = {{Optics, Photonics, and Digital Technologies for Imaging Applications V}},
  title        = {{{Classification of brain tissue with optical coherence tomography by employing texture analysis}}},
  doi          = {{10.1117/12.2307701}},
  year         = {{2018}},
}

@inproceedings{64376,
  author       = {{Hofmann, Martin R. and Gerhardt, Nils Christopher and Finkeldey, Markus and Göring, Lena}},
  booktitle    = {{Practical Holography XXXII: Displays, Materials, and Applications}},
  title        = {{{Digital holography for the investigation of buried structures with a common-path reflection microscope}}},
  doi          = {{10.1117/12.2289524}},
  year         = {{2018}},
}

@inproceedings{64379,
  author       = {{Lindemann, Markus and Gerhardt, Nils Christopher and Hofmann, Martin R. and Pusch, Tobias and Michalzik, Rainer and Scherübl, Sebastian}},
  booktitle    = {{Semiconductor Lasers and Laser Dynamics VIII}},
  title        = {{{Thermally-induced birefringence in VCSELs - approaching the limits}}},
  doi          = {{10.1117/12.2306215}},
  year         = {{2018}},
}

@inproceedings{64375,
  author       = {{Lindemann, Markus and Gerhardt, Nils Christopher and Hofmann, Martin and Pusch, Tobias and Michalzik, Rainer}},
  booktitle    = {{Vertical-Cavity Surface-Emitting Lasers XXII}},
  title        = {{{Demonstrating ultrafast polarization dynamics in spin-VCSELs}}},
  doi          = {{10.1117/12.2289560}},
  year         = {{2018}},
}

@inproceedings{64378,
  author       = {{Lindemann, Markus and Gerhardt, Nils Christopher and Hofmann, Martin R. and Michalzik, Rainer and Pusch, Tobias}},
  booktitle    = {{Semiconductor Lasers and Laser Dynamics VIII}},
  title        = {{{Spin lasers for optical data communication}}},
  doi          = {{10.1117/12.2306464}},
  year         = {{2018}},
}

@inproceedings{64377,
  author       = {{Lindemann, Markus and Gerhardt, Nils Christopher and Hofmann, Martin R. and Michalzik, Rainer and Pusch, Tobias}},
  booktitle    = {{Vertical-Cavity Surface-Emitting Lasers XXII}},
  title        = {{{Electrical birefringence tuning of VCSELs}}},
  doi          = {{10.1117/12.2295917}},
  year         = {{2018}},
}

@inproceedings{64374,
  author       = {{Gerhardt, Nils Christopher and Neutsch, Krisztian and Göring, Lena}},
  booktitle    = {{Nanoimaging and Nanospectroscopy VI}},
  title        = {{{Common-path digital holographic microscopy for 3D nanoparticle localization}}},
  doi          = {{10.1117/12.2321175}},
  year         = {{2018}},
}

@inproceedings{64380,
  author       = {{Gerhardt, Nils Christopher and Xu, Gaofeng and Žutić, Igor}},
  booktitle    = {{APS March Meeting 2018}},
  title        = {{{Toward ultrafast spin lasers?}}},
  year         = {{2018}},
}