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2020 – today
- 2023
[i19]Sebastian Lotter, Lukas Brand, Vahid Jamali, Maximilian Schäfer, Helene M. Loos, Harald Unterweger, Sandra Greiner, Jens Kirchner, Christoph Alexiou, Dietmar Drummer, Georg Fischer, Andrea Buettner, Robert Schober:
Experimental Research in Synthetic Molecular Communications - Part I: Overview and Short-Range Systems. CoRR abs/2301.06417 (2023)- [i18]Sebastian Lotter, Lukas Brand, Vahid Jamali, Maximilian Schäfer, Helene M. Loos, Harald Unterweger, Sandra Greiner, Jens Kirchner, Christoph Alexiou, Dietmar Drummer, Georg Fischer, Andrea Buettner, Robert Schober:
Experimental Research in Synthetic Molecular Communications - Part II: Long-Range Communication. CoRR abs/2301.06424 (2023) - [i17]Lukas Brand, Maike Scherer, Sebastian Lotter, Maximilian Schäfer, Andreas Burkovski, Heinrich Sticht, Kathrin Castiglione, Robert Schober:
Switchable Signaling Molecules for Media Modulation: Fundamentals, Applications, and Research Directions. CoRR abs/2302.10356 (2023) - 2022
- [j4]Lukas Brand
, Moritz Garkisch, Sebastian Lotter, Maximilian Schäfer, Andreas Burkovski, Heinrich Sticht, Kathrin Castiglione, Robert Schober:
Media Modulation Based Molecular Communication. IEEE Trans. Commun. 70(11): 7207-7223 (2022) - [c21]Sebastian Lotter, Michael Taynnan Barros, Robert Schober, Maximilian Schäfer:
Signal Reception With Generic Three-State Receptors in Synaptic MC. GLOBECOM 2022: 4529-4534 - [c20]Lukas Brand, Moritz Garkisch, Sebastian Lotter, Maximilian Schäfer, Kathrin Castiglione, Robert Schober:
Media Modulation in Molecular Communications. ICC 2022: 3697-3702 - [c19]Maximilian Schäfer, Kun Zhao, Markus Bühren, Anton Kummert:
Context-Aware Scene Prediction Network (CASPNet). ITSC 2022: 3970-3977 - [c18]Maximilian Schäfer, Lukas Brand, Sebastian Lotter, Atakan Büyükoglu, Franz Enzenhofer, Werner Haselmayr, Kathrin Castiglione, Dietmar Appelhans, Robert Schober:
Controlled signaling and transmitter replenishment for MC with functionalized nanoparticles. NANOCOM 2022: 13:1-13:7 - [c17]Sebastian Lotter, Maximilian Schäfer, Robert Schober:
A Chemical Master Equation Model for Synaptic Molecular Communication. WCNC 2022: 2691-2696 - [i16]Sebastian Lotter, Maximilian Schäfer, Robert Schober:
Molecular Noise In Synaptic Communication. CoRR abs/2201.05431 (2022) - [i15]Maximilian Schäfer, Kun Zhao, Markus Bühren, Anton Kummert:
Context-Aware Scene Prediction Network (CASPNet). CoRR abs/2201.06933 (2022) - [i14]Lukas Brand, Moritz Garkisch, Sebastian Lotter, Maximilian Schäfer, Andreas Burkovski, Heinrich Sticht, Kathrin Castiglione, Robert Schober:
Media Modulation based Molecular Communication. CoRR abs/2203.00722 (2022) - [i13]Sebastian Lotter, Michael Taynnan Barros, Robert Schober, Maximilian Schäfer:
Signal Reception With Generic Three-State Receptors in Synaptic MC. CoRR abs/2204.07478 (2022) - [i12]Julian D. Parker, Sebastian J. Schlecht, Rudolf Rabenstein, Maximilian Schäfer:
Physical Modeling using Recurrent Neural Networks with Fast Convolutional Layers. CoRR abs/2204.10125 (2022) - [i11]Maximilian Schäfer, Lukas Brand, Sebastian Lotter, Atakan Büyükoglu, Franz Enzenhofer, Werner Haselmayr, Kathrin Castiglione, Dietmar Appelhans, Robert Schober:
Controlled Signaling and Transmitter Replenishment for MC with Functionalized Nanoparticles. CoRR abs/2206.01471 (2022) - 2021
- [j3]Werner Haselmayr, Jari A. K. Hyttinen, Maximilian Schäfer, Mauro Femminella, Richard J. Morris, Kerstin Lenk, Adam Noel, Michael Taynnan Barros:
Special Issue - Advances in Molecular Communications: Theory, Experiment, and Application. IEEE Trans. Mol. Biol. Multi Scale Commun. 7(2): 69-72 (2021) - [j2]Maximilian Schäfer, Wayan Wicke, Lukas Brand, Rudolf Rabenstein, Robert Schober:
Transfer Function Models for Cylindrical MC Channels With Diffusion and Laminar Flow. IEEE Trans. Mol. Biol. Multi Scale Commun. 7(4): 271-287 (2021) - [c16]Maximilian Schäfer, Yolanda Salinas, Alexander Ruderer, Franz Enzenhofer, Oliver Brüggemann, Robert Schober, Werner Haselmayr:
Channel Modeling for Drug Carrier Matrices. GLOBECOM 2021: 1-6 - [c15]Sebastian Lotter, Maximilian Schäfer, Johannes Zeitler, Robert Schober:
Receptor Saturation Modeling for Synaptic DMC. ICC 2021: 1-6 - [c14]Sebastian Lotter, Lukas Brand, Maximilian Schäfer, Robert Schober:
Statistical Modeling of Airborne Virus Transmission Through Imperfectly Fitted Face Masks. NANOCOM 2021: 10:1-10:7 - [i10]Sebastian Lotter, Maximilian Schäfer, Johannes Zeitler, Robert Schober:
Saturating Receiver and Receptor Competition in Synaptic DMC: Deterministic and Statistical Signal Models. CoRR abs/2103.05341 (2021) - [i9]Maximilian Schäfer, Yolanda Salinas, Alexander Ruderer, Franz Enzenhofer, Oliver Brüggemann, Robert Schober, Werner Haselmayr:
Channel Modeling for Drug Carrier Matrices. CoRR abs/2104.05332 (2021) - [i8]Maximilian Schäfer, Yolanda Salinas, Alexander Ruderer, Franz Enzenhofer, Oliver Brüggemann, Ramón Martínez-Máñez, Rudolf Rabenstein, Robert Schober, Werner Haselmayr:
Channel Responses for the Molecule Release from Spherical Homogeneous Matrix Carriers. CoRR abs/2106.08392 (2021) - [i7]Sebastian Lotter, Maximilian Schäfer, Robert Schober:
A Chemical Master Equation Model for Synaptic Molecular Communication. CoRR abs/2109.14986 (2021) - [i6]Lukas Brand, Moritz Garkisch, Sebastian Lotter, Maximilian Schäfer, Kathrin Castiglione, Robert Schober:
Media Modulation in Molecular Communications. CoRR abs/2110.15744 (2021) - [i5]Lukas Brand, Sebastian Lotter, Vahid Jamali, Robert Schober, Maximilian Schäfer:
Area Rate Efficiency in Multi-Link Molecular Communications. CoRR abs/2111.05175 (2021) - 2020
- [c13]Maximilian Schäfer, Wayan Wicke, Werner Haselmayr, Rudolf Rabenstein, Robert Schober:
Spherical Diffusion Model with Semi-Permeable Boundary: A Transfer Function Approach. ICC 2020: 1-7 - [c12]Maurizio Magarini, Richard J. Morris, Francesca Ratti, Maximilian Schäfer, George W. Bassel, Hamdan Awan, Werner Haselmayr:
A molecular communications framework for understanding the floral transition. NANOCOM 2020: 5:1-5:2 - [i4]Maximilian Schäfer, Wayan Wicke, Lukas Brand, Rudolf Rabenstein, Robert Schober:
Transfer Function Models for Cylindrical MC Channels with Diffusion and Laminar Flow. CoRR abs/2007.01799 (2020) - [i3]Sebastian Lotter, Maximilian Schäfer, Johannes Zeitler, Robert Schober:
Receptor Saturation Modeling for Synaptic DMC. CoRR abs/2010.14828 (2020)
2010 – 2019
- 2019
- [c11]Maximilian Schäfer, Alexander Ruderer, Rudolf Rabenstein:
An Eigenfunction Approach to Parameter Estimation for 1D Diffusion Problems. ECC 2019: 3784-3789 - [c10]Maximilian Schafer, Wayan Wicke, Rudolf Rabenstein, Robert Schober:
Analytical Models for Particle Diffusion and Flow in a Horizontal Cylinder with a Vertical Force. ICC 2019: 1-7 - [c9]Maximilian Schäfer, Rudolf Rabenstein, Sebastian J. Schlecht:
Feedback Structures for a Transfer Function Model of a Circular Vibrating Membrane. WASPAA 2019: 145-149 - [i2]Maximilian Schäfer, Wayan Wicke, Werner Haselmayr, Rudolf Rabenstein, Robert Schober:
Spherical Diffusion Model with Semi-Permeable Boundary: A Transfer Function Approach. CoRR abs/1910.14319 (2019) - 2018
- [j1]Rudolf Rabenstein, Maximilian Schäfer, Christian Strobl:
Transfer function models for distributed-parameter systems with impedance boundary conditions. Int. J. Control 91(12): 2726-2742 (2018) - [c8]Maximilian Schafer, Wayan Wicke, Rudolf Rabenstein, Robert Schober:
An nD Model for a Cylindrical Diffusion-Advection Problem with an Orthogonal Force Component. DSP 2018: 1-5 - [c7]Rudolf Rabenstein, Maximilian Schäfer, Johannes Bauer, Christian Strobl:
A Wave Digital Kalman Filter Approach for Fault Detection in DC Grids: A Case Study. ISCAS 2018: 1-5 - [c6]Christian Strobl, Maximilian Schäfer, Rudolf Rabenstein:
Non-Recursive System Identification and Fault Detection in LVDC and ELVDC Grids. ISCAS 2018: 1-5 - [i1]Maximilian Schäfer, Wayan Wicke, Rudolf Rabenstein, Robert Schober:
Transfer Function Models for Particle Diffusion in a Horizontal Cylindrical Shape with a Vertical Force Component. CoRR abs/1803.10848 (2018) - 2017
- [c5]Maximilian Schafer, Rudolf Rabenstein, Christian Strobl:
A multidimensional transfer function model for frequency dependent transmission lines. ISCAS 2017: 1-4 - [c4]Maximilian Schafer, Rudolf Rabenstein:
Calculation of the transformation kernels for the functional transformation method. nDS 2017: 1-6 - [c3]Maximilian Schafer, Rudolf Rabenstein:
A transfer function model for 1D diffusion processes. nDS 2017: 1-6 - 2016
- [c2]Gunter Dehner, Rudolf Rabenstein, Maximilian Schafer, Christian Strobl:
Analysis of the quantization error in digital multipliers with small wordlength. EUSIPCO 2016: 1848-1852 - [c1]Christian Strobl, Maximilian Schafer, Rudolf Rabenstein:
An analytical fault model for direct current lines. ISCAS 2016: 2142-2145
Coauthor Index
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last updated on 2023-03-22 22:13 CET by the dblp team
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