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ORCIDTimo Ropinski
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- affiliation: University of Ulm, Germany
- affiliation: University of Münster, Germany
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2020 – today
- 2024
[j64]Daniel Wolf
, Tristan Payer, Catharina Silvia Lisson, Christoph Gerhard Lisson, Meinrad Beer, Michael Götz, Timo Ropinski:
Less is More: Selective reduction of CT data for self-supervised pre-training of deep learning models with contrastive learning improves downstream classification performance. Comput. Biol. Medicine 183: 109242 (2024)- [j63]Mark Colley, Sebastian Hartwig, Albin Zeqiri, Timo Ropinski, Enrico Rukzio:
AutoTherm: A Dataset and Benchmark for Thermal Comfort Estimation Indoors and in Vehicles. Proc. ACM Interact. Mob. Wearable Ubiquitous Technol. 8(3): 96:1-96:49 (2024) - [j62]Sergej Geringer, Florian Geiselhart, Alex Bäuerle, Dominik Dec, Olivia G. Odenthal, Guido Reina, Timo Ropinski, Daniel Weiskopf:
mint: Integrating scientific visualizations into virtual reality. J. Vis. 27(6): 1143-1169 (2024) - [j61]Dominik Engel, Sebastian Hartwig, Timo Ropinski:
Monocular Depth Decomposition of Semi-Transparent Volume Renderings. IEEE Trans. Vis. Comput. Graph. 30(7): 3981-3994 (2024) - [c91]Sebastian Koch, Pedro Hermosilla, Narunas Vaskevicius, Mirco Colosi, Timo Ropinski:
Lang3DSG: Language-based contrastive pre-training for 3D Scene Graph prediction. 3DV 2024: 1037-1047 - [c90]Daniel Wolf, Tristan Payer, Catharina Silvia Lisson, Christoph Gerhard Lisson, Meinrad Beer, Michael Götz, Timo Ropinski:
Abstract: Self-supervised Pre-training for Dealing with Small Datasets in Deep Learning for Medical Imaging - Evaluation of Contrastive and Masked Autoencoder Methods. Bildverarbeitung für die Medizin 2024: 157 - [c89]Leon Sick, Dominik Engel, Pedro Hermosilla, Timo Ropinski:
Unsupervised Semantic Segmentation Through Depth-Guided Feature Correlation and Sampling. CVPR 2024: 3637-3646 - [c88]Sebastian Koch, Narunas Vaskevicius, Mirco Colosi, Pedro Hermosilla, Timo Ropinski:
Open3DSG: Open-Vocabulary 3D Scene Graphs from Point Clouds with Queryable Objects and Open-Set Relationships. CVPR 2024: 14183-14193 - [c87]Hannah Kniesel, Leon Sick, Tristan Payer, Tim Bergner, Kavitha Shaga Devan, Clarissa Read, Paul Walther, Timo Ropinski, Pedro Hermosilla:
Weakly Supervised Virus Capsid Detection with Image-Level Annotations in Electron Microscopy Images. ICLR 2024 - [c86]Ngan V. T. Nguyen, Feng Liang, Dominik Engel, Ciril Bohak, Ondrej Strnad, Timo Ropinski, Ivan Viola:
Towards Differentiable Electron Microscopy Simulation: Methods and Applications. PacificVis 2024: 62-71 - [c85]Jana Franceska Funke, Michael Wolf, Christian van Onzenoodt, Katja Rogers, Timo Ropinski, Enrico Rukzio:
A Wall I Enjoy: Motivating Gentle Full-Body Movements Through Touchwall Interaction Compared to Standing and Sitting Smartphone Usage. IMX 2024: 201-218 - [c84]Sebastian Koch, Pedro Hermosilla, Narunas Vaskevicius, Mirco Colosi, Timo Ropinski:
SGRec3D: Self-Supervised 3D Scene Graph Learning via Object-Level Scene Reconstruction. WACV 2024: 3392-3402 - [i43]Sebastian Koch, Narunas Vaskevicius, Mirco Colosi, Pedro Hermosilla, Timo Ropinski:
Open3DSG: Open-Vocabulary 3D Scene Graphs from Point Clouds with Queryable Objects and Open-Set Relationships. CoRR abs/2402.12259 (2024) - [i42]Leon Sick, Dominik Engel, Pedro Hermosilla, Timo Ropinski:
Attention-Guided Masked Autoencoders For Learning Image Representations. CoRR abs/2402.15172 (2024) - [i41]Sebastian Hartwig, Dominik Engel, Leon Sick, Hannah Kniesel, Tristan Payer, Poonam Poonam, Michael Glöckler, Alex Bäuerle, Timo Ropinski:
Evaluating Text-to-Image Synthesis: Survey and Taxonomy of Image Quality Metrics. CoRR abs/2403.11821 (2024) - 2023
- [j60]Patrik Puchert, Timo Ropinski:
A3GC-IP: Attention-oriented adjacency adaptive recurrent graph convolutions for human pose estimation from sparse inertial measurements. Comput. Graph. 117: 96-104 (2023) - [j59]Jaegul Choo, Timo Ropinski, Yifan Hu:
Editorial: Guest Editors' Introduction: Special Section on IEEE PacificVis 2023. IEEE Trans. Vis. Comput. Graph. 29(6): 2847-2848 (2023) - [j58]Ngan V. T. Nguyen, Ciril Bohak, Dominik Engel, Peter Mindek, Ondrej Strnad, Peter Wonka, Sai Li, Timo Ropinski, Ivan Viola:
Finding Nano-Ötzi: Cryo-Electron Tomography Visualization Guided by Learned Segmentation. IEEE Trans. Vis. Comput. Graph. 29(10): 4198-4214 (2023) - [j57]Christian van Onzenoodt, Pere-Pau Vázquez, Timo Ropinski:
Out of the Plane: Flower versus Star Glyphs to Support High-Dimensional Exploration in Two-Dimensional Embeddings. IEEE Trans. Vis. Comput. Graph. 29(12): 5468-5482 (2023) - [j56]Alex Bäuerle, Patrick Albus, Raphael Störk, Tina Seufert, Timo Ropinski:
exploRNN: teaching recurrent neural networks through visual exploration. Vis. Comput. 39(9): 4323-4338 (2023) - [c83]Alex Bäuerle, Christian van Onzenoodt, Daniel Jönsson, Timo Ropinski:
Semantic Hierarchical Exploration of Large Image Datasets. EuroVis (Short Papers) 2023: 103-107 - [c82]Michael Schelling, Pedro Hermosilla, Timo Ropinski:
Weakly-Supervised Optical Flow Estimation for Time-of-Flight. WACV 2023: 2134-2143 - [i40]Patrik Puchert, Poonam Poonam, Christian van Onzenoodt, Timo Ropinski:
LLMMaps - A Visual Metaphor for Stratified Evaluation of Large Language Models. CoRR abs/2304.00457 (2023) - [i39]Sebastian Hartwig, Christian van Onzenoodt, Pedro Hermosilla, Timo Ropinski:
ClusterNet: A Perception-Based Clustering Model for Scattered Data. CoRR abs/2304.14185 (2023) - [i38]Daniel Wolf, Tristan Payer, Catharina Silvia Lisson, Christoph Gerhard Lisson, Meinrad Beer, Timo Ropinski, Michael Götz:
Dealing with Small Datasets for Deep Learning in Medical Imaging: An Evaluation of Self-Supervised Pre-Training on CT Scans Comparing Contrastive and Masked Autoencoder Methods for Convolutional Models. CoRR abs/2308.06534 (2023) - [i37]Dominik Engel, Leon Sick, Timo Ropinski:
Leveraging Self-Supervised Vision Transformers for Neural Transfer Function Design. CoRR abs/2309.01408 (2023) - [i36]Leon Sick, Dominik Engel, Pedro Hermosilla, Timo Ropinski:
Spatially Guiding Unsupervised Semantic Segmentation Through Depth-Informed Feature Distillation and Sampling. CoRR abs/2309.12378 (2023) - [i35]Sebastian Koch, Pedro Hermosilla, Narunas Vaskevicius, Mirco Colosi, Timo Ropinski:
SGRec3D: Self-Supervised 3D Scene Graph Learning via Object-Level Scene Reconstruction. CoRR abs/2309.15702 (2023) - [i34]Sebastian Koch, Pedro Hermosilla, Narunas Vaskevicius, Mirco Colosi, Timo Ropinski:
Lang3DSG: Language-based contrastive pre-training for 3D Scene Graph prediction. CoRR abs/2310.16494 (2023) - 2022
- [j55]Alex Bäuerle, Christian van Onzenoodt, Simon der Kinderen, Jimmy Johansson Westberg, Daniel Jönsson, Timo Ropinski:
Where did my Lines go? Visualizing Missing Data in Parallel Coordinates. Comput. Graph. Forum 41(3): 235-246 (2022) - [j54]Sebastian Hartwig, Michael Schelling, Christian van Onzenoodt, Pere-Pau Vázquez, Pedro Hermosilla, Timo Ropinski:
Learning Human Viewpoint Preferences from Sparsely Annotated Models. Comput. Graph. Forum 41(6): 453-466 (2022) - [j53]Nan Cao, Timo Ropinski, Jian Zhao:
Guest Editors' Introduction: Special Section on IEEE PacificVis 2022. IEEE Trans. Vis. Comput. Graph. 28(6): 2299-2300 (2022) - [c81]Michael Schelling, Pedro Hermosilla, Timo Ropinski:
RADU: Ray-Aligned Depth Update Convolutions for ToF Data Denoising. CVPR 2022: 661-670 - [c80]Hannah Kniesel, Timo Ropinski, Tim Bergner, Kavitha Shaga Devan, Clarissa Read, Paul Walther, Tobias Ritschel, Pedro Hermosilla:
Clean Implicit 3D Structure from Noisy 2D STEM Images. CVPR 2022: 20730-20740 - [c79]Pedro Hermosilla, Michael Schelling, Tobias Ritschel, Timo Ropinski:
Variance-Aware Weight Initialization for Point Convolutional Neural Networks. ECCV (28) 2022: 74-89 - [c78]Adam Celarek, Pedro Hermosilla, Bernhard Kerbl, Timo Ropinski, Michael Wimmer:
Gaussian Mixture Convolution Networks. ICLR 2022 - [i33]Alex Bäuerle, Aybuke Gul Turker, Ken Burke, Osman Aka, Timo Ropinski, Christina Greer, Mani Varadarajan:
Visual Identification of Problematic Bias in Large Label Spaces. CoRR abs/2201.06386 (2022) - [i32]Adam Celarek, Pedro Hermosilla, Bernhard Kerbl, Timo Ropinski, Michael Wimmer:
Gaussian Mixture Convolution Networks. CoRR abs/2202.09153 (2022) - [i31]Hannah Kniesel, Timo Ropinski, Tim Bergner, Kavitha Shaga Devan, Clarissa Read, Paul Walther, Tobias Ritschel, Pedro Hermosilla:
Clean Implicit 3D Structure from Noisy 2D STEM Images. CoRR abs/2203.15434 (2022) - [i30]Ngan V. T. Nguyen, Feng Liang, Dominik Engel, Ciril Bohak, Peter Wonka, Timo Ropinski, Ivan Viola:
Differentiable Electron Microscopy Simulation: Methods and Applications for Visualization. CoRR abs/2205.04464 (2022) - [i29]Pedro Hermosilla, Timo Ropinski:
Contrastive Representation Learning for 3D Protein Structures. CoRR abs/2205.15675 (2022) - [i28]Alex Bäuerle, Daniel Jönsson, Timo Ropinski:
Neural Activation Patterns (NAPs): Visual Explainability of Learned Concepts. CoRR abs/2206.10611 (2022) - [i27]Dominik Engel, Sebastian Hartwig, Timo Ropinski:
Monocular Depth Estimation for Semi-Transparent Volume Renderings. CoRR abs/2206.13282 (2022) - [i26]Michael Schelling, Pedro Hermosilla, Timo Ropinski:
Weakly-Supervised Optical Flow Estimation for Time-of-Flight. CoRR abs/2210.05298 (2022) - [i25]Mark Colley, Sebastian Hartwig, Albin Zeqiri, Timo Ropinski, Enrico Rukzio:
AutoTherm: A Dataset and Ablation Study for Thermal Comfort Prediction in Vehicles. CoRR abs/2211.08257 (2022) - 2021
- [j52]André Müller, Ludwig Lausser, Adalbert F. X. Wilhelm, Timo Ropinski, Matthias Platzer, Heiko Neumann, Hans A. Kestler:
A perceptually optimised bivariate visualisation scheme for high-dimensional fold-change data. Adv. Data Anal. Classif. 15(2): 463-480 (2021) - [j51]Michael Schelling, Pedro Hermosilla, Pere-Pau Vázquez, Timo Ropinski:
Enabling Viewpoint Learning through Dynamic Label Generation. Comput. Graph. Forum 40(2): 413-423 (2021) - [j50]Christian van Onzenoodt, Gurprit Singh, Timo Ropinski, Tobias Ritschel:
Blue Noise Plots. Comput. Graph. Forum 40(2): 425-433 (2021) - [j49]Patrik Puchert, Pedro Hermosilla, Tobias Ritschel, Timo Ropinski:
Data-driven deep density estimation. Neural Comput. Appl. 33(23): 16773-16807 (2021) - [j48]Dominik Engel, Timo Ropinski:
Deep Volumetric Ambient Occlusion. IEEE Trans. Vis. Comput. Graph. 27(2): 1268-1278 (2021) - [j47]Alex Bäuerle, Christian van Onzenoodt, Timo Ropinski:
Net2Vis - A Visual Grammar for Automatically Generating Publication-Tailored CNN Architecture Visualizations. IEEE Trans. Vis. Comput. Graph. 27(6): 2980-2991 (2021) - [j46]Julian Kreiser, Pedro Hermosilla, Timo Ropinski:
Void Space Surfaces to Convey Depth in Vessel Visualizations. IEEE Trans. Vis. Comput. Graph. 27(10): 3913-3925 (2021) - [c77]Pedro Hermosilla, Marco Schäfer, Matej Lang, Gloria Fackelmann, Pere-Pau Vázquez, Barbora Kozlíková, Michael Krone, Tobias Ritschel, Timo Ropinski:
Intrinsic-Extrinsic Convolution and Pooling for Learning on 3D Protein Structures. ICLR 2021 - [c76]Michael Stegmaier, Dominik Engel, Jannik Olbrich, Timo Ropinski, Matthias Tichy:
Property-Based Testing for Visualization Development. VisGap@EuroVis 2021: 9-17 - [i24]Christian van Onzenoodt, Gurprit Singh, Timo Ropinski, Tobias Ritschel:
Blue Noise Plots. CoRR abs/2102.04072 (2021) - [i23]Patrik Puchert, Pedro Hermosilla, Tobias Ritschel, Timo Ropinski:
Data-driven deep density estimation. CoRR abs/2107.11085 (2021) - [i22]Patrik Puchert, Timo Ropinski:
Human Pose Estimation from Sparse Inertial Measurements through Recurrent Graph Convolution. CoRR abs/2107.11214 (2021) - [i21]Michael Schelling, Pedro Hermosilla, Timo Ropinski:
RADU: Ray-Aligned Depth Update Convolutions for ToF Data Denoising. CoRR abs/2111.15513 (2021) - [i20]Pedro Hermosilla, Michael Schelling, Tobias Ritschel, Timo Ropinski:
Variance-Aware Weight Initialization for Point Convolutional Neural Networks. CoRR abs/2112.03777 (2021) - 2020
- [j45]Guido Reina, Hank Childs, Kresimir Matkovic, Katja Bühler, Manuela Waldner, David Pugmire, Barbora Kozlíková, Timo Ropinski, Patric Ljung, Takayuki Itoh, M. Eduard Gröller, Michael Krone:
The moving target of visualization software for an increasingly complex world. Comput. Graph. 87: 12-29 (2020) - [j44]Christian van Onzenoodt, Anke Huckauf, Timo Ropinski:
On the perceptual influence of shape overlap on data-comparison using scatterplots . Comput. Graph. 90: 169-181 (2020) - [j43]Alex Bäuerle, Heiko Neumann, Timo Ropinski:
Classifier-Guided Visual Correction of Noisy Labels for Image Classification Tasks. Comput. Graph. Forum 39(3): 195-205 (2020) - [j42]Sebastian Maisch, Timo Ropinski:
Interactive Subsurface Scattering for Materials With High Scattering Distances. Comput. Graph. Forum 39(6): 465-479 (2020) - [j41]Daniel Jönsson, Peter Steneteg, Erik Sundén, Rickard Englund, Sathish Kottravel, Martin Falk, Anders Ynnerman, Ingrid Hotz, Timo Ropinski:
Inviwo - A Visualization System with Usage Abstraction Levels. IEEE Trans. Vis. Comput. Graph. 26(11): 3241-3254 (2020) - [c75]Gabriel Eilertsen, Daniel Jönsson, Timo Ropinski, Jonas Unger, Anders Ynnerman:
Classifying the Classifier: Dissecting the Weight Space of Neural Networks. ECAI 2020: 1119-1126 - [c74]Hannah Kniesel, Timo Ropinski, Pedro Hermosilla:
Real-Time Visualization of 3D Amyloid-Beta Fibrils from 2D Cryo-EM Density Maps. VCBM 2020: 115-125 - [i19]Gabriel Eilertsen, Daniel Jönsson, Timo Ropinski, Jonas Unger, Anders Ynnerman:
Classifying the classifier: dissecting the weight space of neural networks. CoRR abs/2002.05688 (2020) - [i18]Michael Schelling, Pedro Hermosilla, Pere-Pau Vázquez, Timo Ropinski:
Enabling Viewpoint Learning through Dynamic Label Generation. CoRR abs/2003.04651 (2020) - [i17]Hartwig Anzt, Felix Bach, Stephan Druskat, Frank Löffler, Axel Loewe, Bernhard Y. Renard, Gunnar Seemann, Alexander Struck, Elke Achhammer, Piush Aggarwal, Franziska Appel, Michael Bader, Lutz Brusch, Christian Busse, Gerasimos Chourdakis, Piotr Wojtek Dabrowski, Peter Ebert, Bernd Flemisch, Sven Friedl, Bernadette Fritzsch, Maximilian D. Funk, Volker Gast, Florian Goth, Jean-Noël Grad, Sibylle Hermann, Florian Hohmann, Stephan Janosch, Dominik Kutra, Jan Linxweiler, Thilo Muth, Wolfgang Peters-Kottig, Fabian Rack, Fabian H. C. Raters, Stephan Rave, Guido Reina, Malte Reißig, Timo Ropinski, Jörg Schaarschmidt, Heidi Seibold, Jan P. Thiele, Benjamin Uekermann, Stefan Unger, Rudolf Weeber:
An Environment for Sustainable Research Software in Germany and Beyond: Current State, Open Challenges, and Call for Action. CoRR abs/2005.01469 (2020) - [i16]Pedro Hermosilla, Marco Schäfer, Matej Lang, Gloria Fackelmann, Pere-Pau Vázquez, Barbora Kozlíková, Michael Krone, Tobias Ritschel, Timo Ropinski:
ProteiNN: Intrinsic-Extrinsic Convolution and Pooling for Scalable Deep Protein Analysis. CoRR abs/2007.06252 (2020) - [i15]Dominik Engel, Timo Ropinski:
Deep Volumetric Ambient Occlusion. CoRR abs/2008.08345 (2020) - [i14]Alex Bäuerle, Raphael Störk, Timo Ropinski:
exploRNN: Understanding Recurrent Neural Networks through Visual Exploration. CoRR abs/2012.06326 (2020) - [i13]Hartwig Anzt, Felix Bach, Stephan Druskat, Frank Löffler, Axel Loewe, Bernhard Y. Renard, Gunnar Seemann, Alexander Struck, Elke Achhammer, Piush Aggarwal, Franziska Appel, Michael Bader, Lutz Brusch, Christian Busse, Gerasimos Chourdakis, Piotr Wojciech Dabrowski, Peter Ebert, Bernd Flemisch, Sven Friedl, Bernadette Fritzsch, Maximilian D. Funk, Volker Gast, Florian Goth, Jean-Noël Grad, Sibylle Hermann, Florian Hohmann, Stephan Janosch, Dominik Kutra, Jan Linxweiler, Thilo Muth, Wolfgang Peters-Kottig, Fabian Rack, Fabian H. C. Raters, Stephan Rave, Guido Reina, Malte Reißig, Timo Ropinski, Jörg Schaarschmidt, Heidi Seibold, Jan P. Thiele, Benjamin Uekermann, Stefan Unger, Rudolf Weeber:
An environment for sustainable research software in Germany and beyond: current state, open challenges, and call for action. F1000Research 9: 295 (2020) - [i12]Renata Georgia Raidou, Barbora Kozlíková, Johanna Beyer, Timo Ropinski, Issei Fujishiro:
Formalizing Biological and Medical Visualization (NII Shonan Meeting 167). NII Shonan Meet. Rep. 2020 (2020)
2010 – 2019
- 2019
- [j40]Pedro Hermosilla, Sebastian Maisch, Tobias Ritschel, Timo Ropinski:
Deep-learning the Latent Space of Light Transport. Comput. Graph. Forum 38(4): 207-217 (2019) - [j39]Simon Besenthal, Sebastian Maisch, Timo Ropinski:
Multi-Resolution Rendering for Computationally Expensive Lighting Effects. J. WSCG 27(1) (2019) - [j38]David Duran, Pedro Hermosilla, Timo Ropinski, Barbora Kozlíková, Àlvar Vinacua, Pere-Pau Vázquez:
Visualization of Large Molecular Trajectories. IEEE Trans. Vis. Comput. Graph. 25(1): 987-996 (2019) - [j37]Stefan Bruckner, Tobias Isenberg, Timo Ropinski, Alexander Wiebel:
A Model of Spatial Directness in Interactive Visualization. IEEE Trans. Vis. Comput. Graph. 25(8): 2514-2528 (2019) - [c73]Pedro Hermosilla Casajus, Tobias Ritschel, Timo Ropinski:
Total Denoising: Unsupervised Learning of 3D Point Cloud Cleaning. ICCV 2019: 52-60 - [d3]Peter Steneteg, Rickard Englund, Martin Falk, Daniel Jönsson, Erik Sundén, Anke Friederici, Jochen Jankowai, Albin Bergström, Dominik Engel, Sathish Kottravel, Robin Skånberg, Tino Weinkauf, Anders Ynnerman, Ingrid Hotz, Timo Ropinski:
Inviwo. Zenodo, 2019
- [d2]Peter Steneteg, Rickard Englund, Martin Falk, Daniel Jönsson, Erik Sundén, Anke Friederici, Jochen Jankowai, Albin Bergström, Dominik Engel, Sathish Kottravel, Robin Skånberg, Tino Weinkauf, Anders Ynnerman, Ingrid Hotz, Timo Ropinski:
Inviwo. Zenodo, 2019 - [d1]Peter Steneteg, Rickard Englund, Martin Falk, Daniel Jönsson, Erik Sundén, Anke Friederici, Jochen Jankowai, Albin Bergström, Dominik Engel, Sathish Kottravel, Robin Skånberg, Tino Weinkauf, Anders Ynnerman, Ingrid Hotz, Timo Ropinski:
Inviwo. Zenodo, 2019 - [i11]Alex Bäuerle, Timo Ropinski:
Net2Vis: Transforming Deep Convolutional Networks into Publication-Ready Visualizations. CoRR abs/1902.04394 (2019) - [i10]Sebastian Hartwig, Timo Ropinski:
Training Object Detectors on Synthetic Images Containing Reflecting Materials. CoRR abs/1904.00824 (2019) - [i9]Pedro Hermosilla, Tobias Ritschel, Timo Ropinski:
Total Denoising: Unsupervised Learning of 3D Point Cloud Cleaning. CoRR abs/1904.07615 (2019) - [i8]Simon Besenthal, Sebastian Maisch, Timo Ropinski:
Multi-Resolution Rendering for Computationally Expensive Lighting Effects. CoRR abs/1906.04576 (2019) - 2018
- [j36]Philipp Henzler, Volker Rasche, Timo Ropinski, Tobias Ritschel:
Single-image Tomography: 3D Volumes from 2D Cranial X-Rays. Comput. Graph. Forum 37(2): 377-388 (2018) - [j35]Pedro Hermosilla, Pere-Pau Vázquez, Àlvar Vinacua, Timo Ropinski:
A General Illumination Model for Molecular Visualization. Comput. Graph. Forum 37(3): 367-378 (2018) - [j34]Julian Kreiser, Monique Meuschke, Gabriel Mistelbauer, Bernhard Preim, Timo Ropinski:
A Survey of Flattening-Based Medical Visualization Techniques. Comput. Graph. Forum 37(3): 597-624 (2018) - [j33]Julian Kreiser, J. Freedman, Timo Ropinski:
Visually Supporting Multiple Needle Placement in Irreversible Electroporation Interventions. Comput. Graph. Forum 37(6): 59-71 (2018) - [j32]Rickard Englund, Timo Ropinski:
Quantitative and Qualitative Analysis of the Perception of Semi-Transparent Structures in Direct Volume Rendering. Comput. Graph. Forum 37(6): 174-187 (2018) - [j31]Pedro Hermosilla, Tobias Ritschel, Pere-Pau Vázquez, Àlvar Vinacua, Timo Ropinski:
Monte Carlo convolution for learning on non-uniformly sampled point clouds. ACM Trans. Graph. 37(6): 235 (2018) - [j30]Julian Kreiser, Alexander Hann, Eugen Zizer, Timo Ropinski:
Decision Graph Embedding for High-Resolution Manometry Diagnosis. IEEE Trans. Vis. Comput. Graph. 24(1): 873-882 (2018) - [c72]Bernhard Preim, Timo Ropinski, Petra Isenberg:
A Critical Analysis of the Evaluation Practice in Medical Visualization. VCBM@MICCAI 2018: 45-56 - [c71]Pedro Hermosilla, Sebastian Maisch, Pere-Pau Vázquez, Timo Ropinski:
Improving Perception of Molecular Surface Visualizations by Incorporating Translucency Effects. VCBM@MICCAI 2018: 185-195 - [i7]Pedro Hermosilla, Tobias Ritschel, Pere-Pau Vázquez, Àlvar Vinacua, Timo Ropinski:
Monte Carlo Convolution for Learning on Non-Uniformly Sampled Point Clouds. CoRR abs/1806.01759 (2018) - [i6]Julian Kreiser, Pedro Hermosilla, Timo Ropinski:
Void Space Surfaces to Convey Depth in Vessel Visualizations. CoRR abs/1806.07729 (2018) - [i5]Alex Bäuerle, Heiko Neumann, Timo Ropinski:
Training De-Confusion: An Interactive, Network-Supported Visual Analysis System for Resolving Errors in Image Classification Training Data. CoRR abs/1808.03114 (2018) - [i4]Pedro Hermosilla, Sebastian Maisch, Tobias Ritschel, Timo Ropinski:
Deep-learning the Latent Space of Light Transport. CoRR abs/1811.04756 (2018) - [i3]Daniel Jönsson, Peter Steneteg, Erik Sundén, Rickard Englund, Sathish Kottravel, Martin Falk, Anders Ynnerman, Ingrid Hotz, Timo Ropinski:
Inviwo - A Visualization System with Usage Abstraction Levels. CoRR abs/1811.12517 (2018) - 2017
- [j29]Sebastian Maisch, Timo Ropinski:
Spatial Adjacency Maps for Translucency Simulation under General Illumination. Comput. Graph. Forum 36(2): 443-453 (2017) - [j28]Alexander Bock, Åsa Svensson, Alexander Kleiner, Jonas Lundberg, Timo Ropinski:
A Visualization-Based Analysis System for Urban Search & Rescue Mission Planning Support. Comput. Graph. Forum 36(6): 148-159 (2017) - [j27]Sathish Kottravel, Riccardo Volpi, Mathieu Linares, Timo Ropinski, Ingrid Hotz:
Visual Analysis of Stochastic Trajectory Ensembles in Organic Solar Cell Design. Informatics 4(3): 25 (2017) - [j26]Pedro Hermosilla, Jorge Estrada, Victor Guallar, Timo Ropinski, Àlvar Vinacua, Pere-Pau Vázquez:
Physics-Based Visual Characterization of Molecular Interaction Forces. IEEE Trans. Vis. Comput. Graph. 23(1): 731-740 (2017) - [j25]José Díaz, Timo Ropinski, Isabel Navazo, Enrico Gobbetti, Pere-Pau Vázquez:
An experimental study on the effects of shading in 3D perception of volumetric models. Vis. Comput. 33(1): 47-61 (2017) - [j24]Pedro Hermosilla, Michael Krone, Victor Guallar, Pere-Pau Vázquez, Àlvar Vinacua, Timo Ropinski:
Interactive GPU-based generation of solvent-excluded surfaces. Vis. Comput. 33(6-8): 869-881 (2017) - [c70]Christian van Onzenoodt, Julian Kreiser, Dominique Heer, Timo Ropinski:
Evaluating the Influence of Stereoscopy on Cluster Perception in Scatterplots. SIGRAD 2017: 143:004 - [c69]Jan Malzahn, Barbora Kozlíková, Timo Ropinski:
Protein Tunnel Reprojection for Physico-Chemical Property Analysis. VCBM 2017: 1-10 - [e5]Stefan Bruckner, Timo Ropinski:
38th Annual Conference of the European Association for Computer Graphics, Eurographics 2017 - Dirk Bartz Prize, Lyon, France, April 24-28, 2017. Eurographics Association 2017 [contents] - [i2]Philipp Henzler, Volker Rasche, Timo Ropinski, Tobias Ritschel:
Single-image Tomography: 3D Volumes from 2D X-Rays. CoRR abs/1710.04867 (2017) - 2016
- [j23]Bernhard Preim, Alexandra Baer, Douglas W. Cunningham, Tobias Isenberg, Timo Ropinski:
A Survey of Perceptually Motivated 3D Visualization of Medical Image Data. Comput. Graph. Forum 35(3): 501-525 (2016) - [j22]Sebastian Maisch, Robin Skånberg, Timo Ropinski:
A Comparative Study of Mipmapping Techniques for Interactive Volume Visualization. J. WSCG 24(2): 35-42 (2016) - [j21]Robin Skånberg, Pere-Pau Vázquez, Victor Guallar, Timo Ropinski:
Real-Time Molecular Visualization Supporting Diffuse Interreflections and Ambient Occlusion. IEEE Trans. Vis. Comput. Graph. 22(1): 718-727 (2016) - [c68]Rickard Englund, Sathish Kottravel, Timo Ropinski:
A crowdsourcing system for integrated and reproducible evaluation in scientific visualization. PacificVis 2016: 40-47 - [c67]Rickard Englund, Timo Ropinski:
Evaluating the perception of semi-transparent structures in direct volume rendering techniques. SIGGRAPH Asia Symposium on Visualization 2016: 9:1-9:8 - [c66]Ingrid Hotz, Jochen Jankowai, Rickard Englund, Timo Ropinski:
Interactive 4D MRI blood flow exploration and analysis using line predicates. SIGRAD 2016: 127:006 - [c65]Rickard Englund, Timo Ropinski, Ingrid Hotz:
Coherence Maps for Blood Flow Exploration. VCBM/MedViz 2016: 79-88 - [c64]Julian Kreiser, Timo Ropinski:
Classifying Medical Projection Techniques based on Parameterization Attribute Preservation. EuroRV³@EuroVis 2016: 15-17 - [p3]Khoa Tan Nguyen, Håkan Gauffin, Anders Ynnerman, Timo Ropinski:
Quantitative Analysis of Knee Movement Patterns Through Comparative Visualization. Visualization in Medicine and Life Sciences III 2016: 265-284 - 2015
- [j20]Erik Sundén, Sathish Kottravel, Timo Ropinski:
Multimodal volume illumination. Comput. Graph. 50: 47-60 (2015) - [j19]Stefan Lindholm, Martin Falk, Erik Sundén, Alexander Bock, Anders Ynnerman, Timo Ropinski:
Hybrid Data Visualization Based on Depth Complexity Histogram Analysis. Comput. Graph. Forum 34(1): 74-85 (2015) - [c63]Erik Sundén, Timo Ropinski:
Efficient volume illumination with multiple light sources through selective light updates. PacificVis 2015: 231-238 - [c62]Sathish Kottravel, Martin Falk, Erik Sundén, Timo Ropinski:
Coverage-based opacity estimation for interactive Depth of Field in molecular visualization. PacificVis 2015: 255-262 - [c61]Alexander Wiebel, Tobias Isenberg, Stefan Bruckner, Timo Ropinski:
Tools and Techniques for Direct Volume Interaction. Eurographics (Tutorials) 2015 - [c60]Alexander Bock, Asher Pembroke, M. Leila Mays, Lutz Rastaetter, Timo Ropinski, Anders Ynnerman:
Visual verification of space weather ensemble simulations. SciVis 2015: 17-24 - [c59]Erik Sundén, Peter Steneteg, Sathish Kottravel, Daniel Jönsson, Rickard Englund, Martin Falk, Timo Ropinski:
Inviwo - An extensible, multi-purpose visualization framework. SciVis 2015: 163-164 - [c58]Dimitrios Felekidis, Peter Steneteg, Timo Ropinski:
Advanced Visualization Techniques for Laparoscopic Liver Surgery. SIGRAD 2015: 120:008 - [e4]Hans-Christian Hege, Timo Ropinski:
36th Annual Conference of the European Association for Computer Graphics, Eurographics 2015 - Dirk Bartz Prize, Zurich, Switzerland, May 4-8, 2015. Eurographics Association 2015 [contents] - 2014
- [j18]Daniel Jönsson, Erik Sundén, Anders Ynnerman, Timo Ropinski:
A Survey of Volumetric Illumination Techniques for Interactive Volume Rendering. Comput. Graph. Forum 33(1): 27-51 (2014) - [j17]Július Parulek, Daniel Jönsson, Timo Ropinski, Stefan Bruckner, Anders Ynnerman, Ivan Viola:
Continuous Levels-of-Detail and Visual Abstraction for Seamless Molecular Visualization. Comput. Graph. Forum 33(6): 276-287 (2014) - [j16]Tiago Etiene, Daniel Jönsson, Timo Ropinski, Carlos Eduardo Scheidegger, João Luiz Dihl Comba, Luis Gustavo Nonato, Robert M. Kirby, Anders Ynnerman, Cláudio T. Silva:
Verifying Volume Rendering Using Discretization Error Analysis. IEEE Trans. Vis. Comput. Graph. 20(1): 140-154 (2014) - [c57]Rickard Englund, Timo Ropinski:
Ultrasound Surface Extraction Using Radial Basis Functions. ISVC (2) 2014: 163-172 - [c56]Alexander Bock, Alexander Kleiner, Jonas Lundberg, Timo Ropinski:
An interactive visualization system for urban search & rescue mission planning. SSRR 2014: 1-7 - [c55]Erik Sundén, Alexander Bock, Daniel Jönsson, Anders Ynnerman, Timo Ropinski:
Interaction techniques as a communication channel when presenting 3D visualizations. 3DVis@IEEE VIS 2014: 61-65 - [c54]Alexander Bock, Alexander Kleiner, Jonas Lundberg, Timo Ropinski:
Supporting Urban Search & Rescue Mission Planning through Visualization-Based Analysis. VMV 2014: 47-54 - [p2]Åsmund Birkeland, Veronika Soltészová, Dieter Hönigmann, Odd Helge Gilja, Svein Brekke, Timo Ropinski, Ivan Viola:
The Ultrasound Visualization Pipeline. Scientific Visualization 2014: 283-303 - [e3]Ivan Viola, Katja Bühler, Timo Ropinski:
Eurographics Workshop on Visual Computing for Biology and Medicine, VCBM 2014, Vienna, Austria, 2014. Proceedings. Eurographics Association 2014, ISBN 978-3-905674-62-0 [contents] - 2013
- [c53]Alexander Bock, Norbert Lang, Gianpaolo Evangelista, Ralph Lehrke, Timo Ropinski:
Guiding Deep Brain Stimulation interventions by fusing multimodal uncertainty regions. PacificVis 2013: 97-104 - [c52]Tan Khoa Nguyen, Timo Ropinski:
Large-scale multiple sequence alignment visualization through gradient vector flow analysis. BioVis 2013: 9-16 - [c51]Tan Khoa Nguyen, Anders Ynnerman, Timo Ropinski:
Analyzing and Reducing DTI Tracking Uncertainty by Combining Deterministic and Stochastic Approaches. ISVC (1) 2013: 266-279 - [c50]Július Parulek, Timo Ropinski, Ivan Viola:
Seamless Visual Abstraction of Molecular Surfaces. SCCG 2013: 107-114 - [c49]Tan Khoa Nguyen, Timo Ropinski:
Feature Tracking in Time-Varying Volumetric Data through Scale Invariant Feature Transform. SIGRAD 2013: 11-16 - [c48]Neda Rostamzadeh, Daniel Jönsson, Timo Ropinski:
A Comparison of Volumetric Illumination Methods by Considering their Underlying Mathematical Models. SIGRAD 2013: 35-40 - [e2]Jonas Unger, Timo Ropinski:
Proceedings of SIGRAD 2013, Visual Computing, June 13-14, 2013, Norrköping, Sweden. Linköping Electronic Conference Proceedings 94, Linköping University Electronic Press 2013 [contents] - 2012
- [j15]Timo Ropinski, Stefan Diepenbrock, Stefan Bruckner, Klaus H. Hinrichs, M. Eduard Gröller:
Unified Boundary-Aware Texturing for Interactive Volume Rendering. IEEE Trans. Vis. Comput. Graph. 18(11): 1942-1955 (2012) - [j14]Alexander Bock, Erik Sundén, Bingchen Liu, Burkhard Wünsche, Timo Ropinski:
Coherency-Based Curve Compression for High-Order Finite Element Model Visualization. IEEE Trans. Vis. Comput. Graph. 18(12): 2315-2324 (2012) - [j13]Daniel Jönsson, Joel Kronander, Timo Ropinski, Anders Ynnerman:
Historygrams: Enabling Interactive Global Illumination in Direct Volume Rendering using Photon Mapping. IEEE Trans. Vis. Comput. Graph. 18(12): 2364-2371 (2012) - [c47]Daniel Jönsson, Per Ganestam, Michael C. Doggett, Anders Ynnerman, Timo Ropinski:
Explicit Cache Management for Volume Ray-Casting on Parallel Architectures. EGPGV@Eurographics 2012: 31-40 - [c46]Daniel Jönsson, Erik Sundén, Anders Ynnerman, Timo Ropinski:
Interactive Volume Rendering with Volumetric Illumination. Eurographics (State of the Art Reports) 2012: 53-74 - [c45]Bingchen Liu, Alexander Bock, Timo Ropinski, Martyn P. Nash, Poul M. F. Nielsen, Burkhard Wünsche:
GPU-accelerated direct volume rendering of finite element data sets. IVCNZ 2012: 109-114 - [c44]Stefan Diepenbrock, Timo Ropinski:
From Imprecise User Input to Precise Vessel Segmentations. VCBM 2012: 65-72 - [c43]Tan Khoa Nguyen, Alexander Bock, Anders Ynnerman, Timo Ropinski:
Deriving and Visualizing Uncertainty in Kinetic PET Modeling. VCBM 2012: 107-114 - [e1]Timo Ropinski, Anders Ynnerman, Charl P. Botha, Jos B. T. M. Roerdink:
Proceedings of the Eurographics Workshop on Visual Computing for Biomedicine, VCBM 2012, Norrköping, Sweden, 2012. Eurographics Association 2012, ISBN 978-3-905674-38-5 [contents] - [i1]Åsmund Birkeland, Veronika Soltészová, Dieter Hönigmann, Odd Helge Gilja, Svein Brekke, Timo Ropinski, Ivan Viola:
The Ultrasound Visualization Pipeline - A Survey. CoRR abs/1206.3975 (2012) - 2011
- [j12]Timo Ropinski, Steffen Oeltze, Bernhard Preim:
Survey of glyph-based visualization techniques for spatial multivariate medical data. Comput. Graph. 35(2): 392-401 (2011) - [j11]Florian Lindemann, Timo Ropinski:
About the Influence of Illumination Models on Image Comprehension in Direct Volume Rendering. IEEE Trans. Vis. Comput. Graph. 17(12): 1922-1931 (2011) - [j10]Erik Sundén, Anders Ynnerman, Timo Ropinski:
Image Plane Sweep Volume Illumination. IEEE Trans. Vis. Comput. Graph. 17(12): 2125-2134 (2011) - [c42]Stefan Diepenbrock, Timo Ropinski, Klaus H. Hinrichs:
Context-aware volume navigation. PacificVis 2011: 11-18 - [c41]Stefan Diepenbrock, Jörg-Stefan Praßni, Florian Lindemann, Hans-Werner Bothe, Timo Ropinski:
Interactive Visualization Techniques for Neurosurgery Planning. Eurographics (Dirk Bartz Prize) 2011: 13-16 - 2010
- [j9]Timo Ropinski, Christian Döring, Christof Rezk-Salama:
Advanced Volume Illumination with Unconstrained Light Source Positioning. IEEE Computer Graphics and Applications 30(6): 29-41 (2010) - [j8]Jörg-Stefan Praßni, Timo Ropinski, Klaus H. Hinrichs:
Uncertainty-Aware Guided Volume Segmentation. IEEE Trans. Vis. Comput. Graph. 16(6): 1358-1365 (2010) - [c40]Jörg-Stefan Praßni, Timo Ropinski, Jörg Mensmann, Klaus H. Hinrichs:
Shape-based transfer functions for volume visualization. PacificVis 2010: 9-16 - [c39]Timo Ropinski, Christian Döring, Christof Rezk-Salama:
Interactive volumetric lighting simulating scattering and shadowing. PacificVis 2010: 169-176 - [c38]Jörg Mensmann, Timo Ropinski, Klaus H. Hinrichs:
An Advanced Volume Raycasting Technique using GPU Stream Processing. GRAPP 2010: 190-198 - [c37]Jennis Meyer-Spradow, Timo Ropinski, Jörg Mensmann, Klaus H. Hinrichs:
Interactive Design and Debugging of GPU-based Volume Visualizations. GRAPP 2010: 239-245 - [c36]Bingchen Liu, Burkhard Wünsche, Timo Ropinski:
Visualization by Example - A Constructive Visual Component-based Interface for Direct Volume Rendering. GRAPP 2010: 254-259 - [c35]Florian Lindemann, Timo Ropinski:
Advanced Light Material Interaction for Direct Volume Rendering. VG@Eurographics 2010: 101-108 - [c34]Jörg Mensmann, Timo Ropinski, Klaus H. Hinrichs:
A GPU-Supported Lossless Compression Scheme for Rendering Time-Varying Volume Data. VG@Eurographics 2010: 109-116 - [c33]Christian Meß, Timo Ropinski:
Efficient Acquisition and Clustering of Local Histograms for Representing Voxel Neighborhoods. VG@Eurographics 2010: 117-124 - [c32]Jörg Mensmann, Timo Ropinski, Klaus H. Hinrichs:
Slab-Based Raycasting: Exploiting GPU Computing for Volume Visualization. VISIGRAPP (Selected Papers) 2010: 246-259
2000 – 2009
- 2009
- [j7]Jennis Meyer-Spradow, Timo Ropinski, Jörg Mensmann, Klaus H. Hinrichs:
Voreen: A Rapid-Prototyping Environment for Ray-Casting-Based Volume Visualizations. IEEE Computer Graphics and Applications 29(6): 6-13 (2009) - [j6]Timo Ropinski, Sven Hermann, Rainer Reich, Michael Schäfers, Klaus H. Hinrichs:
Multimodal Vessel Visualization of Mouse Aorta PET/CT Scans. IEEE Trans. Vis. Comput. Graph. 15(6): 1515-1522 (2009) - [c31]Markus Hadwiger, Patric Ljung, Christof Rezk-Salama, Timo Ropinski:
GPU-Based Volume Ray-Casting with Advanced Illumination. Eurographics (Tutorials) 2009: 39-211 - [c30]Timo Ropinski, Klaus H. Hinrichs, Jens Kasten:
GPU-based Volume Ray-casting supporting Specular Reflection and Refraction. GRAPP 2009: 219-222 - [c29]Markus Hadwiger, Patric Ljung, Christof Rezk-Salama, Timo Ropinski:
Advanced illumination techniques for GPU-based volume raycasting. SIGGRAPH Courses 2009: 2:1-2:166 - [c28]Timo Ropinski, Ivan Viola, Martin Biermann, Helwig Hauser, Klaus H. Hinrichs:
Multimodal Visualization with Interactive Closeups. TPCG 2009: 17-24 - [c27]Jörg-Stefan Praßni, Timo Ropinski, Klaus H. Hinrichs:
Efficient Boundary Detection and Transfer Function Generation in Direct Volume Rendering. VMV 2009: 285-294 - 2008
- [j5]Timo Ropinski, Jennis Meyer-Spradow, Stefan Diepenbrock, Jörg Mensmann, Klaus H. Hinrichs:
Interactive Volume Rendering with Dynamic Ambient Occlusion and Color Bleeding. Comput. Graph. Forum 27(2): 567-576 (2008) - [j4]Jörg Mensmann, Timo Ropinski, Klaus H. Hinrichs:
Interactive Cutting Operations for Generating Anatomical Illustrations from Volumetric Data Sets. J. WSCG 16(1-3): 89-96 (2008) - [j3]Jennis Meyer-Spradow, Lars Stegger, Christian Döring, Timo Ropinski, Klaus H. Hinrichs:
Glyph-Based SPECT Visualization for the Diagnosis of Coronary Artery Disease. IEEE Trans. Vis. Comput. Graph. 14(6): 1499-1506 (2008) - [c26]Frank Steinicke, Gerd Bruder, Timo Ropinski, Klaus H. Hinrichs:
Poster: Generic Redirected Walking & Dynamic Passive Haptics: Evaluation and Implications for Virtual Locomotion Interfaces. 3DUI 2008: 147-148 - [c25]Timo Ropinski, Borislav Petkov, Larissa Fabritz, Klaus H. Hinrichs:
Interactive Reconstruction and Visualization of Dynamic 3D Ultrasound Data Sets. GRAPP 2008: 308-315 - [c24]Frank Steinicke, Timo Ropinski, Gerd Bruder, Klaus H. Hinrichs:
The holodeck construction manual. SIGGRAPH Posters 2008: 97 - [c23]Markus Hadwiger, Patric Ljung, Christof Rezk-Salama, Timo Ropinski:
Advanced illumination techniques for GPU volume raycasting. SIGGRAPH ASIA Courses 2008: 1:1-1:166 - [c22]Timo Ropinski, Bernhard Preim:
Taxonomy and Usage Guidelines for Glyph-based Medical Visualization. SimVis 2008: 121-138 - [c21]Timo Ropinski, Jörg-Stefan Praßni, Frank Steinicke, Klaus H. Hinrichs:
Stroke-Based Transfer Function Design. VG/PBG@SIGGRAPH 2008: 41-48 - [c20]Jörg Mensmann, Timo Ropinski, Klaus H. Hinrichs:
Accelerating Volume Raycasting using Occlusion Frustums. VG/PBG@SIGGRAPH 2008: 147-154 - [c19]Frank Steinicke, Timo Ropinski, Gerd Bruder, Klaus H. Hinrichs, Harald Frenz, Markus Lappe:
A Universal Virtual Locomotion System: Supporting Generic Redirected Walking and Dynamic Passive Haptics within Legacy 3D Graphics Applications. VR 2008: 291-292 - [p1]Jennis Meyer-Spradow, Timo Ropinski, Klaus H. Hinrichs:
Supporting Depth and Motion Perception in Medical Volume Data. Visualization in Medicine and Life Sciences 2008: 121-133 - 2007
- [c18]Timo Ropinski, Frank Steinicke, Jennis Meyer-Spradow, Klaus H. Hinrichs:
Automatic integration of foliage into 3D city models - real-time tree extraction and rendering based on seasonal large scale aerial pictures. GRAPP (GM/R) 2007: 299-304 - [c17]Frank Steinicke, Timo Ropinski, Gerd Bruder, Klaus H. Hinrichs:
3D Modeling and Design Supported Via Interscopic Interaction Strategies. HCI (4) 2007: 1160-1169 - [c16]Frank Steinicke, Timo Ropinski, Gerd Bruder, Klaus H. Hinrichs:
Towards Applicable 3D User Interfaces for Everyday Working Environments. INTERACT (1) 2007: 546-559 - [c15]Timo Ropinski, Frank Steinicke, Gerd Bruder, Klaus H. Hinrichs:
Focus+Context Resolution Adaption for Autostereoscopic Displays. Smart Graphics 2007: 188-193 - [c14]Timo Ropinski, Michael Specht, Jennis Meyer-Spradow, Klaus H. Hinrichs, Bernhard Preim:
Surface Glyphs for Visualizing Multimodal Volume Data. VMV 2007: 3-12 - [c13]Timo Ropinski, Jörg-Stefan Praßni, Jan Roters, Klaus H. Hinrichs:
Internal Labels as Shape Cues for Medical Illustration. VMV 2007: 203-212 - [c12]Frank Steinicke, Timo Ropinski, Gerd Bruder, Klaus H. Hinrichs:
Interscopic User Interface Concepts for Fish Tank Virtual Reality Systems. VR 2007: 27-34 - 2006
- [j2]Timo Ropinski, Jennis Meyer-Spradow, Frank Steinicke, Klaus H. Hinrichs:
Design of a user-oriented application for the exploration of medical datasets. Elektrotech. Informationstechnik 123(4): 131-134 (2006) - [j1]Timo Ropinski, Frank Steinicke, Klaus H. Hinrichs:
Visual Exploration of Seismic Volume Datasets. J. WSCG 14(1-3): 73-80 (2006) - [c11]Frank Steinicke, Timo Ropinski, Klaus H. Hinrichs, Jörg Mensmann:
Urban city planning in semi-immersive virtual reality systems. GRAPP 2006: 192-199 - [c10]Timo Ropinski, Frank Steinicke, Klaus H. Hinrichs:
Visually Supporting Depth Perception in Angiography Imaging. Smart Graphics 2006: 93-104 - [c9]Timo Ropinski, Frank Steinicke, Gerd Bruder, Klaus H. Hinrichs:
Simultaneously viewing monoscopic and stereoscopic content on vertical-interlaced autostereoscopic displays. SIGGRAPH Research Posters 2006: 68 - 2005
- [c8]Frank Steinicke, Timo Ropinski, Klaus H. Hinrichs:
A generic virtual reality software system's architecture and application. ICAT 2005: 220-227 - [c7]Timo Ropinski, Frank Steinicke, Klaus H. Hinrichs:
A constrained road-based VR navigation technique for travelling in 3D city models. ICAT 2005: 228-235 - [c6]Frank Steinicke, Klaus H. Hinrichs, Timo Ropinski:
Virtual Reflections and Virtual Shadows in Mixed Reality Environments. INTERACT 2005: 1018-1021 - [c5]Timo Ropinski, Frank Steinicke, Klaus H. Hinrichs:
Tentative Results in Focus-Based Medical Volume Visualization. Smart Graphics 2005: 218-221 - [c4]Timo Ropinski, Klaus H. Hinrichs:
Interactive Volume Visualization Techniques for Subsurface Data. VISUAL 2005: 121-131 - [c3]Frank Steinicke, Timo Ropinski, Klaus H. Hinrichs:
Multimodal Interaction Metaphors for Manipulation of Distant Objects in Immersive Virtual Environments. WSCG (Short Papers) 2005: 45-48 - 2004
- [b1]Timo Ropinski:
3D magic lenses and virtual reflections - real-time approaches for improving interactive visualization. University of Münster, Germany, 2004, pp. I-XII, 1-134 - [c2]Frank Steinicke, Timo Ropinski, Klaus H. Hinrichs:
Object Selection in Virtual Environments using an Improved Virtual Pointer Metaphor. ICCVG 2004: 320-326 - [c1]Timo Ropinski, Klaus H. Hinrichs:
Real-Time Rendering of 3D Magic Lenses having arbitrary convex Shapes. WSCG 2004: 379-386
Coauthor Index
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