default search action
Markus Hofer
Person information
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
showing all ?? records
2020 – today
- 2024
- [c38]Hussein Hammoud, Yuning Zhang, Zihang Cheng, Seun Sangodoyin, Markus Hofer, Faruk Pasic, Thomas M. Pohl, Radek Závorka, Ales Prokes, Thomas Zemen, Christoph F. Mecklenbräuker, Andreas F. Molisch:
A Novel Low-Cost Channel Sounder for Double-Directionally Resolved Measurements in the MmWave band. ICC 2024: 3195-3201 - [c37]Faruk Pasic, Markus Hofer, Mariam Mussbah, Sebastian Caban, Stefan Schwarz, Thomas Zemen, Christoph F. Mecklenbräuker:
Channel Estimation for mmWave MIMO Using Sub-6 GHz Out-of-Band Information. SmartNets 2024: 1-6 - [c36]Hamed Radpour, Markus Hofer, Lukas Walter Mayer, Andreas Hofmann, Martin Schiefer, Thomas Zemen:
Active Reconfigurable Intelligent Surface for the Millimeter-Wave Frequency Band: Design and Measurement Results. WCNC 2024: 1-6 - [i10]Hamed Radpour, Markus Hofer, David Löschenbrand, Lukas Walter Mayer, Andreas Hofmann, Martin Schiefer, Thomas Zemen:
Reconfigurable Intelligent Surface for Industrial Automation: mmWave Propagation Measurement, Simulation, and Control Algorithm Requirements. CoRR abs/2402.04844 (2024) - 2023
- [j14]David Löschenbrand
, Markus Hofer
Spectral Efficiency of Time-Variant Massive MIMO Using Wiener Prediction. IEEE Commun. Lett. 27(4): 1225-1229 (2023) - [c35]David Löschenbrand, Markus Hofer, Lukas Eller, Markus Rupp, Thomas Zemen:
Machine Learning-Based Channel Prediction for Widely Distributed Massive MIMO with Real-World Data. ACSSC 2023: 982-987 - [c34]Anja Dakic, Benjamin Rainer, Markus Hofer, Thomas Zemen:
Frame Error Rate Prediction for Non-Stationary Wireless Vehicular Communication Links. PIMRC 2023: 1-6 - [c33]Faruk Pasic, Markus Hofer, Danilo Radovic, Herbert Groll, Sebastian Caban, Thomas Zemen
Quantifying the Reproducibility of Multi-Band High Speed Wireless Channel Measurements. PIMRC 2023: 1-6 - [c32]Faruk Pasic, Markus Hofer, Mariam Mussbah, Herbert Groll, Thomas Zemen
Statistical Evaluation of Delay and Doppler Spreads in sub-6 GHz and mmWave Vehicular Channels. VTC2023-Spring 2023: 1-6 - [c31]Anja Dakic, Benjamin Rainer, Markus Hofer, Stefan Zelenbaba, Stefan Teschl, Guo Nan, Peter Priller
Hardware-in-the-Loop Framework for Testing Wireless V2X Communication. WCNC 2023: 1-6 - [c30]Markus Hofer, David Löschenbrand, Stefan Zelenbaba, Gerhard Humer, Benjamin Rainer, Thomas Zemen
Massive MIMO Channel Measurements for a Railway Station Scenario. WCNC 2023: 1-6 - [i9]Hamed Radpour, Markus Hofer, Lukas Walter Mayer, Andreas Hofmann, Martin Schiefer, Thomas Zemen:
Active Reconfigurable Intelligent Surfaces for the Millimeter-Wave Frequency Band: System Design and Measurement. CoRR abs/2306.04515 (2023) - [i8]Faruk Pasic, Markus Hofer, Mariam Mussbah, Sebastian Caban, Stefan Schwarz, Thomas Zemen, Christoph F. Mecklenbräuker:
Channel Estimation for mmWave MIMO using sub-6 GHz Out-of-Band Information. CoRR abs/2311.08996 (2023) - 2022
- [j13]David Löschenbrand
Towards Cell-Free Massive MIMO: A Measurement-Based Analysis. IEEE Access 10: 89232-89247 (2022) - [j12]Herbert Groll
Scatterer Identification by Atomic Norm Minimization in Vehicular mm-Wave Propagation Channels. IEEE Access 10: 102334-102354 (2022) - [c29]Stefan Zelenbaba, Benjamin Rainer, Markus Hofer, Thomas Zemen:
Wireless Digital Twin for Assessing the Reliability of Vehicular Communication Links. GLOBECOM (Workshops) 2022: 1034-1039 - [c28]Benjamin Rainer, Stefan Zelenbaba, Anja Dakic, Markus Hofer, David Löschenbrand, Thomas Zemen, Xiaochun Ye, Guo Nan, Stefan Teschl, Peter Priller
WiLi - Vehicular Wireless Channel Dataset enriched with LiDAR and Radar Data. GLOBECOM 2022: 4770-4775 - [c27]Markus Hofer, David Löschenbrand, Stefan Zelenbaba, Anja Dakic, Benjamin Rainer, Thomas Zemen
Wireless 3GHz and 30 GHz Vehicle-to-Vehicle Measurements in an Urban Street Scenario. VTC Fall 2022: 1-5 - [i7]David Löschenbrand, Markus Hofer, Laura Bernadó, Stefan Zelenbaba, Thomas Zemen:
Towards Cell-Free Massive MIMO: A Measurement-Based Analysis. CoRR abs/2207.01280 (2022) - 2021
- [j11]Anja Dakic
Real-Time Vehicular Wireless System-Level Simulation. IEEE Access 9: 23202-23217 (2021) - [j10]Anja Dakic
Corrections to "Real-Time Vehicular Wireless System-Level Simulation". IEEE Access 9: 66266-66267 (2021) - [j9]Stefan Zelenbaba
Multi-Node Vehicular Wireless Channels: Measurements, Large Vehicle Modeling, and Hardware-in-the-Loop Evaluation. IEEE Access 9: 112439-112453 (2021) - [c26]Georg Kail, Hannes Muhr, Janos Gila, Martin Schiefer, Reinhard Hladik, Markus Hofer, Stefan Zelenbaba, Thomas Zemen
A Highly Reliable Ultralow-Latency Wireless Solution for Industrial Control Loops: Design and Evaluation. ACSCC 2021: 8-12 - [c25]Aina Val Martí, Nemanja Vokic, Markus Hofer, Dinka Milovancev, Thomas Zemen
Hybrid Analogue / Digitized Radio-over-Fibre Downlink Through Orthogonal Optical mm-Wave and 10 Gb/s Baseband Transport. ECOC 2021: 1-4 - [c24]Markus Hofer, David Löschenbrand, Jiri Blumenstein, Herbert Groll, Stefan Zelenbaba, Benjamin Rainer, Laura Bernadó, Josef Vychodil, Tomas Mikulasek, Erich Zöchmann, Seun Sangodoyin, Hussein Hammoud, Bernhard Schrenk, Robert Langwieser, Stefan Pratschner, Ales Prokes, Andreas F. Molisch, Christoph F. Mecklenbräuker, Thomas Zemen:
Wireless Vehicular Multiband Measurements in Centimeterwave and Millimeterwave Bands. PIMRC 2021: 836-841 - [c23]Benjamin Rainer, Markus Hofer, Stefan Zelenbaba, David Löschenbrand, Thomas Zemen, Xiaochun Ye, Peter Priller
Scalable, resource and locality-aware selection of active scatterers in Geometry-based stochastic channel models. PIMRC 2021: 885-891 - 2020
- [c22]David Löschenbrand, Markus Hofer, Thomas Zemen:
Orthogonal Precoding with Channel Prediction for High Mobility Massive MIMO. PIMRC 2020: 1-6 - [c21]Benjamin Rainer, David Löschenbrand, Stefan Zelenbaba, Markus Hofer, Thomas Zemen:
Towards a Non-Stationary Correlated Fading Process for Diffuse Scattering in Ray Tracing. PIMRC 2020: 1-7 - [c20]Stefan Zelenbaba, Benjamin Rainer, Markus Hofer, Anja Dakic, David Löschenbrand, Thomas Zemen:
Packet Error Rate Based Validation Method for an OpenStreetMap Geometry-Based Channel Model. VTC Fall 2020: 1-5 - [c19]Stefan Zelenbaba, David Löschenbrand, Markus Hofer, Anja Dakic, Benjamin Rainer, Gerhard Humer, Thomas Zemen:
A Scalable Mobile Multi-Node Channel Sounder. WCNC 2020: 1-6 - [i6]Patrick Schwab, Arash Mehrjou, Sonali Parbhoo, Leo Anthony Celi, Jürgen Hetzel, Markus Hofer, Bernhard Schölkopf, Stefan Bauer:
Real-time Prediction of COVID-19 related Mortality using Electronic Health Records. CoRR abs/2008.13412 (2020) - [i5]Anja Dakic, Markus Hofer, Benjamin Rainer, Stefan Zelenbaba, Laura Bernadó, Thomas Zemen:
Real-Time Vehicular Wireless System-Level Simulation. CoRR abs/2012.12331 (2020)
2010 – 2019
- 2019
- [j8]Erich Zöchmann
Position-Specific Statistics of 60 GHz Vehicular Channels During Overtaking. IEEE Access 7: 14216-14232 (2019) - [j7]Thomas Zemen
Orthogonally Precoded Massive MIMO for High Mobility Scenarios. IEEE Access 7: 132979-132990 (2019) - [j6]Markus Hofer
Real-Time Geometry-Based Wireless Channel Emulation. IEEE Trans. Veh. Technol. 68(2): 1631-1645 (2019) - [c18]David Löschenbrand, Markus Hofer, Benjamin Rainer, Thomas Zemen:
Empirical and Simulated Performance Evaluation of Distributed Massive MIMO. ACSSC 2019: 952-956 - [c17]Stefan Zelenbaba, Markus Hofer, David Löschenbrand, Georg Kail, Martin Schiefer, Thomas Zemen:
Spatial Properties of Industrial Wireless Ultra-Reliable Low-Latency Communication MIMO Links. ACSSC 2019: 1054-1058 - [c16]Stefan Pratschner, Martin Lerch, Daniel Schützenhöfer, Markus Hofer, Jiri Blumenstein
Sparsity in the Delay-Doppler Domain for Measured 60 GHz Vehicle-to-Infrastructure Communication Channels. ICC Workshops 2019: 1-6 - [c15]Christoph Schmittner, Sebastian Chlup, Arndt Bonitz, Martin Latzenhofer, Markus Hofer, Carina Kloibhofer, Thomas Raab, Edvin Spahovic, Thomas Doms:
Preliminary Considerations for a Cooperative Intelligent Transport System Cybersecurity Reference Architecture. ICCVE 2019: 1-6 - [c14]Douglas Cirqueira
Customer Purchase Behavior Prediction in E-commerce: A Conceptual Framework and Research Agenda. NFMCP@PKDD/ECML 2019: 119-136 - [c13]Jiri Blumenstein, Seun Sangodoyin, Andreas F. Molisch, Ales Prokes, Josef Vychodil, Tomas Mikulasek, Erich Zöchmann, Herbert Groll
Vehicle-to-Vehicle Millimeter-Wave Channel Measurements at 56-64 GHz. VTC Fall 2019: 1-5 - [c12]Markus Hofer, Thomas Zemen, Laura Bernadó, Benjamin Rainer
Evaluation of Vehicle-in-the-Loop Tests for Wireless V2X Communication. VTC Fall 2019: 1-5 - [i4]Markus Hofer, Thomas Zemen:
Real-Time Wireless Channel Emulation for Autonomous Vehicles. ERCIM News 2019(117) (2019) - 2018
- [j5]Bernhard Schrenk
Visible-Light Multi-Gb/s Transmission Based on Resonant Cavity LED With Optical Energy Feed. IEEE J. Sel. Areas Commun. 36(1): 175-184 (2018) - [c11]Jiri Blumenstein
Measured High-Resolution Power-Delay Profiles of Nonstationary Vehicular Millimeter Wave Channels. PIMRC 2018: 1-5 - [c10]Thomas Zemen, Markus Hofer, David Loeschenbrand, Christoph Pacher
Iterative Detection for Orthogonal Precoding in Doubly Selective Channels. PIMRC 2018: 1-7 - [c9]Ales Prokes
Time-Domain Broadband 60 GHz Channel Sounder for Vehicle-to-Vehicle Channel Measurement. VNC 2018: 1-7 - [c8]Markus Hofer, Zhinan Xu, Dimitrios Vlastaras, Bernhard Schrenk, David Loeschenbrand, Fredrik Tufvesson, Thomas Zemen:
Validation of a Real-Time Geometry-Based Stochastic Channel Model for Vehicular Scenarios. VTC Spring 2018: 1-5 - 2017
- [j4]Zhinan Xu, Markus Hofer, Thomas Zemen:
A Time-Variant Channel Prediction and Feedback Framework for Interference Alignment. IEEE Trans. Veh. Technol. 66(7): 5961-5973 (2017) - [c7]Bernhard Schrenk, Markus Hofer, Michael Hentschel, Thomas Zemen:
Semi-passive power/wavelength splitting node with integrated spectrum monitoring for reconfigurable PON. OFC 2017: 1-3 - [c6]Bernhard Schrenk, Markus Hofer, Fabian Laudenbach, Hannes Hübel, Thomas Zemen:
Low-cost visible light communication system based on off-the-shelf LED for up to 4.3 Gb/s/λ transmission. OFC 2017: 1-3 - [c5]Markus Hofer, Zhinan Xu, Thomas Zemen:
Real-time channel emulation of a geometry-based stochastic channel model on a SDR platform. SPAWC 2017: 1-5 - [i3]Zhinan Xu, Markus Hofer, Thomas Zemen:
A time-variant channel prediction and feedback framework for interference alignment. CoRR abs/1701.00376 (2017) - [i2]Thomas Zemen, Markus Hofer, David Loeschenbrand, Christoph Pacher:
Orthogonal Precoding for Ultra Reliable Wireless Communication Links. CoRR abs/1710.09912 (2017) - [i1]Thomas Zemen, Markus Hofer, David Loeschenbrand:
Low-Complexity Equalization for Orthogonal Time and Frequency Signaling (OTFS). CoRR abs/1710.09916 (2017) - 2015
- [c4]Mingming Gan, Zhinan Xu, Markus Hofer, Gerhard Steinböck
A Sub-Band Divided Ray Tracing Algorithm Using the DPS Subspace in UWB Indoor Scenarios. VTC Spring 2015: 1-5 - [c3]Markus Hofer, Zhinan Xu, Thomas Zemen:
On the Optimum Number of Hypotheses for Adaptive Reduced-Rank Subspace Selection. VTC Fall 2015: 1-5 - 2014
- [j3]Markus Hofer, Maria Rita Iacò
Optimal Bounds for Integrals with Respect to Copulas and Applications. J. Optim. Theory Appl. 161(3): 999-1011 (2014) - [j2]Christoph Aistleitner, Markus Hofer:
Probabilistic discrepancy bound for Monte Carlo point sets. Math. Comput. 83(287): 1373-1381 (2014) - [c2]Markus Hofer, Thomas Zemen:
Iterative non-stationary channel estimation for LTE downlink communications. ICC Workshops 2014: 26-31 - [c1]Zhinan Xu, Laura Bernadó, Mingming Gan, Markus Hofer, Taimoor Abbas
Relaying for IEEE 802.11p at road intersection using a vehicular non-stationary channel model. WiVeC 2014: 1-6 - 2012
- [j1]Christoph Aistleitner, Markus Hofer:
Probabilistic error bounds for the discrepancy of mixed sequences. Monte Carlo Methods Appl. 18(2): 181-200 (2012)
Coauthor Index
David Loeschenbrand
aka: David Löschenbrand
aka: David Löschenbrand
[c38] [c37] [c36] [i10] [j14] [c35] [c34] [c33] [c32] [c31] [c30] [i9] [i8] [j13] [j12] [c29] [c28] [c27] [i7] [j11] [j10] [j9] [c26] [c25] [c24] [c23] [c22] [c21] [c20] [c19] [i5] [j8] [j7] [j6] [c18] [c17] [c16] [c13] [c12] [i4] [j5] [c11] [c10] [c9] [c8] [j4] [c7] [c6] [c5] [i3] [i2] [i1] [c4] [c3] [c2] [c1]
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from ,
, and
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and
to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from .
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-09-28 01:22 CEST by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by: