@inproceedings{62108, author = {{Luchterhandt, Lars and Govindasamy, Vivek and Wang, Yutong and Scheytt, Christoph and Mueller, Wolfgang and Dömer, Rainer}}, booktitle = {{2025 Forum on Specification & Design Languages (FDL)}}, publisher = {{IEEE}}, title = {{{A Quantitative Guide to Navigate Speed/Accuracy Tradeoffs in System Level Design of RISC-V Processor Grids}}}, doi = {{10.1109/fdl68117.2025.11165408}}, year = {{2025}}, } @inproceedings{58861, author = {{Luchterhandt, Lars and Govindasamy, Vivek and Wang, Yutong and Dömer, Rainer and Müller, Wolfgang and Scheytt, J. Christoph}}, booktitle = {{OSSMPIC - Open Source Solutions for Massively Parallel Integrated Circuits}}, title = {{{Case Study on Combining Open-Source Tool Flows for Grids of Processing Cells}}}, year = {{2025}}, } @article{62148, author = {{Sadiye, Babak and Iftekhar, Mohammed and Müller, Wolfgang and Scheytt, J. Christoph}}, issn = {{1063-8210}}, journal = {{IEEE Transactions on Very Large Scale Integration (VLSI) Systems}}, publisher = {{IEEE}}, title = {{{60-Gb/s 1:4 Demultiplexer in 22-nm FD-SOI Technology Using TSPC Logic: A Circuit-to-System-Level Analysis and Design}}}, doi = {{10.1109/TVLSI.2025.3625787}}, year = {{2025}}, } @inproceedings{61079, abstract = {{We propose a spatio-spectral, combined model-based and data-driven diarization pipeline consisting of TDOA-based segmentation followed by embedding-based clustering. The proposed system requires neither access to multi-channel training data nor prior knowledge about the number or placement of microphones. It works for both a compact microphone array and distributed microphones, with minor adjustments. Due to its superior handling of overlapping speech during segmentation, the proposed pipeline significantly outperforms the single-channel pyannote approach, both in a scenario with a compact microphone array and in a setup with distributed microphones. Additionally, we show that, unlike fully spatial diarization pipelines, the proposed system can correctly track speakers when they change positions.}}, author = {{Cord-Landwehr, Tobias and Gburrek, Tobias and Deegen, Marc and Haeb-Umbach, Reinhold}}, booktitle = {{Proceedings of INTERSPEECH}}, location = {{Rotterdam}}, title = {{{Spatio-spectral diarization of meetings by combining TDOA-based segmentation and speaker embedding-based clustering}}}, doi = {{10.21437/Interspeech.2025-1663}}, year = {{2025}}, } @inproceedings{62164, author = {{Kuhlmann, Michael and Seebauer, Fritz and Wagner, Petra and Häb-Umbach, Reinhold}}, booktitle = {{Interspeech 2025}}, publisher = {{ISCA}}, title = {{{Towards Frame-level Quality Predictions of Synthetic Speech}}}, doi = {{10.21437/interspeech.2025-2190}}, year = {{2025}}, } @phdthesis{62167, abstract = {{Diese Dissertation befasst sich mit der Entwicklung eines induktiv-basierten Lokalisierungsverfahrens mittels planarer Spulen, das auf magnetischer Kopplung beruht. Grundlage ist die elektromagnetische Induktion, bei der sich die entstehende Spannung proportional zur Gegeninduktivität verhält. Das Verfahren arbeitet im physikalischen Nahfeld und im Frequenzbereich von einigen kHz bis MHz, um eine effiziente Kopplung ohne Ausbreitung elektromagnetischer Wellen zu gewährleisten. Im Vergleich zu etablierten Verfahren wie GPS oder Ultraschall zeigt die induktive Ortung Vorteile bei kurzer Reichweite, insbesondere durch hohe Genauigkeit im Zentimeterbereich und geringe Materialabhängigkeit. Zudem lässt sie sich in bestehende Technologien wie bei der drahtlosen Energieübertragung integrieren und durch Sensorfusion mit anderen Verfahren kombinieren. Zur Modellierung und Optimierung werden physikalische Eigenschaften von planaren Spulen und EM-Feldern analysiert und elektrische Ersatzschaltbilder eingesetzt. Die geometriebasierte Berechnung der Gegeninduktivität ermöglicht die Entwicklung und Bewertung geeigneter Ortungsalgorithmen. Stochastische Filterverfahren verbessern zusätzlich die Robustheit gegenüber Umgebungseinflüssen. Abschließend wird eine modulare Simulationsplattform vorgestellt, die als Grundlage für die Generierung von Trainingsdaten sowie zur Weiterentwicklung von Mess-, Ortungs- und Filtermethoden dient.}}, author = {{Lange, Sven}}, pages = {{247}}, publisher = {{Universitätsbibliothek Paderborn}}, title = {{{Analyse und Modellierung eines induktiven Ortungsprozesses unter Berücksichtigung der elektromagnetischen Wechselwirkungen planarer Spulensysteme}}}, doi = {{10.17619/UNIPB/1-2436}}, year = {{2025}}, } @inproceedings{62126, author = {{Iftekhar, Mohammed and Sadiye, Babak and Müller, Wolfgang and Scheytt, J. Christoph}}, booktitle = {{IEEE Nordic Circuits and Systems Conference (NORCAS)}}, location = {{Riga, Latvia}}, title = {{{A 50 Gbps Reference-less NRZ Full-rate Bang-Bang CDR with Automatic Frequency Acquisition in 130 nm SiGe:C BiCMOS Technology}}}, doi = {{10.1109/NorCAS66540.2025.11231203}}, year = {{2025}}, } @inproceedings{62270, author = {{Weizel, Maxim and Malavalli Nagaraju, Harshan Gowda and Scheytt, J. Christoph}}, booktitle = {{2025 IEEE BiCMOS and Compound Semiconductor Integrated Circuits and Technology Symposium (BCICTS)}}, location = {{Phoenix, Arizona, USA}}, publisher = {{IEEE}}, title = {{{A 128 GS/s 2x Time-Interleaved Track and Hold Amplifier in 130nm SiGe BiCMOS}}}, doi = {{10.1109/bcicts63111.2025.11211462}}, year = {{2025}}, } @inproceedings{58856, author = {{Hannemann, Kai Arne and Bütün, Hüseyin Berke and Müller, Wolfgang and Scheytt, J. Christoph}}, booktitle = {{MBMV 2025 - 28. Workshop Methoden und Beschreibungssprachen zur Modellierung und Verifikation von Schaltungen und Systemen}}, isbn = {{978-3-8007-6515-7}}, publisher = {{VDE Verlag}}, title = {{{Verilator and FireSim RTL Simulations on a HPC Cluster: A Comparative Case Study}}}, year = {{2025}}, } @inproceedings{62301, author = {{Dreiling, Dmitrij and Itner, Dominik and Gravenkamp, Hauke and Birk, Carolin and Henning, Bernd}}, booktitle = {{2025 International Congress on Ultrasonics}}, pages = {{102–105}}, publisher = {{AMA Service GmbH}}, title = {{{A Measurement Setup for the Determination of Temperature-Dependent Viscoelastic Material Parameters Using an Ultrasonic Pulse-Echo Technique}}}, doi = {{10.5162/ultrasonic2025/a12-c5}}, year = {{2025}}, } @article{62643, author = {{Schwabe, Tobias and Kress, Christian and Kruse, Stephan and Weizel, Maxim and Rhee, Hanjo and Scheytt, J. Christoph}}, journal = {{Journal of Lightwave Technology}}, keywords = {{Integrated circuit modeling, Capacitance, Silicon, Modulation, Adaptation models, Semiconductor device modeling, Bandwidth, Data communication, electrooptical transmitter, equalization, free-carrier-plasma dispersion effect, modelling, optical modulator, phase shifter, silicon photonics}}, number = {{1}}, pages = {{255--270}}, title = {{{Forward-Biased Silicon Phase Shifter Modeling for Electronic-Photonic Co-Simulation and Validation in a 250 nm EPIC BiCMOS Technology}}}, doi = {{10.1109/JLT.2024.3450949}}, volume = {{43}}, year = {{2025}}, } @inproceedings{62642, author = {{Kruse, Stephan and Brockmeier, Jan and Schwengelbeck, Max and Schwabe, Tobias and Scheytt, J. Christoph}}, booktitle = {{2025 55th European Microwave Conference (EuMC)}}, keywords = {{Phased arrays, Optical fibers, Optical fiber sensors, Laser radar, Optical variables measurement, Apertures, Light emitting diodes, Optical receivers, Optical transmitters, Optical modulation, Lidar, light detection and ranging, FMCW, frequency modulated contentious wave, visible light sensing (VLS), visible light communication (VLC), automotive headlights, light emitting diode (LED), microwave photonics, wireless sensing}}, pages = {{602--605}}, title = {{{A Photonic Assisted Visible Light FMCW Lidar System for Large Aperture Phased Array MIMO Based on LEDs}}}, doi = {{10.23919/EuMC65286.2025.11235259}}, year = {{2025}}, } @article{62644, author = {{Schwabe, Tobias and Kress, Christian and Sadiye, Babak and Kruse, Stephan and Scheytt, J. Christoph}}, journal = {{IEEE Access}}, keywords = {{Optical attenuators, Equalizers, Phase shifters, Optical modulation, Electro-optic modulators, Optical amplifiers, Circuits, Silicon photonics, Optical saturation, Integrated circuit modeling, Data communication, equalization, electro-optical transmitter, silicon photonics, phase shifter, optical modulator, free-carrier plasma dispersion effect, driver architectures, biasing schemes}}, pages = {{192433--192450}}, title = {{{Analysis and Design of Forward Biased Silicon Photonics Phase Shifter Equalizer Circuits}}}, doi = {{10.1109/ACCESS.2025.3629385}}, volume = {{13}}, year = {{2025}}, } @inproceedings{62641, author = {{Kruse, Stephan and Diri, Jabil and Mager, Thomas and Kress, Christian and Scheytt, J. Christoph}}, booktitle = {{2025 55th European Microwave Conference (EuMC)}}, keywords = {{Optical fibers, Integrated optics, Semiconductor device measurement, Laser radar, Optical device fabrication, Photonic integrated circuits, Microwave theory and techniques, Optical fiber devices, Plastics, Substrates, Microwave photonics, photonic radar, optical LO distribution, mechatronic integrated device (MID)}}, pages = {{127--130}}, title = {{{Electrooptical Integration of an Electronic Photonic Integrated Circuit Into Plastic Substrates Using Mid-Technology}}}, doi = {{10.23919/EuMC65286.2025.11235121}}, year = {{2025}}, } @misc{62638, author = {{Kruse, Stephan and Meinecke, Marc-Michael and Gisder, Thomas and Simoni, Renato and González-Huici, Maria Antonia and Greiff, Christian and Mateos-Nunez, David and Danklmayer, Andreas and Ladan, Julien and Kurz, Heiko Gustav}}, title = {{{Antennenvorrichtung zum Aussenden von elektromagnetischer Strahlung für ein Kraftfahrzeug sowie Kraftfahrzeug}}}, year = {{2025}}, } @misc{62639, author = {{Kruse, Stephan and Silberhorn, Christine and Brecht, Benjamin and Schwabe, Tobias}}, title = {{{Optisch basierter Digital-Analog-Umsetzer}}}, year = {{2025}}, } @inproceedings{62163, abstract = {{Zero-shot classifiers based on Contrastive Language-Audio Pretraining (CLAP) models enable classification of given audio into classes defined at test time using text. These models are costly to run with respect to computation and memory requirements. In this work, we propose to build a specialized low-resource classifier for classes pre-defined using text, using a two-stage procedure consisting of zero-shot data set pruning and model compression. First, relevant in-domain data is selected from a source dataset using class label embeddings obtained from a pre-trained CLAP model. This data is then used to distill the audio encoder of a CLAP model. The proposed compression method produces compact audio encoders with slightly reduced accuracy. Note that neither labeled nor unlabeled in-domain audio data is required for its development. We verify by cross-dataset tests that the resulting classifiers are indeed specialized to their task.}}, author = {{Werning, Alexander and Häb-Umbach, Reinhold}}, booktitle = {{Proceedings of the 16th ITG Conference on Speech Communication}}, editor = {{Möller, Sebastian and Gerkmann, Timo and Kolossa, Dorothea}}, location = {{Berlin}}, pages = {{76--80}}, title = {{{A Fully Zero-Shot Approach to Obtaining Specialized and Compact Audio Tagging Models}}}, year = {{2025}}, } @inproceedings{59900, abstract = {{Running state-of-the-art large-scale audio models on edge devices is often infeasible due to their limited storage and computing resources. It is therefore necessary to compress and tune the models for the specific target task and hardware. This is commonly achieved by distilling the audio model, the teacher, to a small target model, the student. However, this approach can be improved by prepending a dataset pruning stage and training the teacher on the pruned data set only, which contains examples relevant to the target task. Recently, CLAP models have emerged that embed audio and text examples in a common embedding space. We use the audio embeddings of the CLAP model for the above pruning stage, which is realized using a domain classifier. After knowledge distillation, the student is eventually fine-tuned on some data from the target domain. The CLAP architecture combines text and audio embedding spaces, which allows to search for data given only a textual description, such as a class label. We show how this can help data pruning.}}, author = {{Werning, Alexander and Häb-Umbach, Reinhold}}, booktitle = {{Proceedings of DAS|DAGA 2025}}, location = {{Copenhagen}}, title = {{{Distilling Efficient Audio Models using Data Pruning with CLAP}}}, year = {{2025}}, } @article{62731, author = {{Meschede, Henning and Knorr, Lukas and Piacentino, Antonio and Markovska, Natasa and Duic, Neven}}, issn = {{0360-5442}}, journal = {{Energy}}, publisher = {{Elsevier BV}}, title = {{{Integrated and demand-responsive energy futures in the context of sustainable development of energy systems}}}, doi = {{10.1016/j.energy.2025.139453}}, year = {{2025}}, } @inproceedings{62271, author = {{Weizel, Maxim and Gudyriev, Sergiy and Zazzi, Andrea and Müller, Juliana and Schwabe, Tobias and Witzens, Jeremy and Scheytt, J. Christoph}}, booktitle = {{2025 32nd IEEE International Conference on Electronics, Circuits and Systems (ICECS)}}, location = {{Marrakesh, Morocco}}, publisher = {{IEEE}}, title = {{{High Voltage (5Vpp) Driver Monolithically Integrated with Thermally Tunable Optical Ring Resonators in a Silicon Photonics Technology}}}, doi = {{10.1109/ICECS66544.2025.11270577}}, year = {{2025}}, }