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ORCIDJanis Noetzel
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2020 – today
- 2024
[j12]Davide Li Calsi, Paul Kohl
, Jinhyeock Choi, Janis Nötzel:
The impact of message losses and retransmissions on quantum cryptographic protocols. Comput. Networks 253: 110735 (2024)- [j11]Zuhra Amiri, Shahram Dehdashti, Kareem H. El-Safty, Igor Litvin, Pere Munar-Vallespir, Janis Nötzel, Simon Sekavcnik:
Quantum advantages for data transmission in future networks: An overview. Comput. Networks 254: 110727 (2024) - [c37]Florian Seitz, Janis Nötzel:
Optimality of Sequential Decoding for the Bosonic Compound Channel. ICC 2024: 1788-1794 - [c36]Janis Nötzel:
Data Transmission over a Bosonic Channel under Classical Noise. ISIT 2024: 1227-1232 - 2023
- [j10]Alonso Viladomat Jasso, Ark Modi, Roberto Ferrara, Christian Deppe, Janis Nötzel, Fred Fung, Maximilian Schädler:
Quantum and Quantum-Inspired Stereographic K Nearest-Neighbour Clustering. Entropy 25(9): 1361 (2023) - [c35]Ark Modi, Alonso Viladomat Jasso, Roberto Ferrara, Christian Deppe, Janis Nötzel, Fred Fung, Maximilian Schädler:
Testing of Hybrid Quantum-Classical K-Means for Nonlinear Noise Mitigation. GLOBECOM 2023: 3179-3184 - [c34]Christian Arendt, Janis Nötzel, Holger Boche:
Detectability of Denial-of-Service Attacks on Arbitrarily Varying Channels with State Constraints. ISIT 2023: 2416-2421 - [c33]Stephen DiAdamo, Janis Nötzel:
The Impact of Quantum Memory Quality on Entanglement Assisted Communication. QCE 2023: 1172-1181 - [c32]Zuhra Amiri, Janis Nötzel:
Comparing Latency and Power Consumption: Quantum vs. Classical Preprocessing. WF-IoT 2023: 1-6 - [c31]Davide Li Calsi, Janis Nötzel:
Quantum Static Remote Attestation. WF-IoT 2023: 1-6 - [p1]Sonai Biswas, Riccardo Bassoli, Janis Nötzel, Christian Deppe, Holger Boche, Frank H. P. Fitzek:
Quantum Satellite Communications. A Roadmap to Future Space Connectivity 2023: 85-104 - [i27]Stephen DiAdamo, Janis Nötzel:
The Impact of Quantum Memory Quality on Entanglement Assisted Communication. CoRR abs/2307.15911 (2023) - 2022
- [c30]Zuhra Amiri, Boulat A. Bash, Janis Nötzel:
Performance of Quantum Preprocessing under Phase Noise. GLOBECOM (Workshops) 2022: 298-303 - [c29]Simon Sekavcnik, Janis Nötzel:
Effects of Quantum Communication in Large-Scale Networks at Minimum Latency. GLOBECOM (Workshops) 2022: 802-807 - [c28]Matthias Frey, Igor Bjelakovic, Janis Nötzel, Slawomir Stanczak:
Semantic Security with Infinite Dimensional Quantum Eavesdropping Channel. ITW 2022: 720-725 - [i26]Matthias Frey, Igor Bjelakovic, Janis Nötzel, Slawomir Stanczak:
Semantic Security with Infinite Dimensional Quantum Eavesdropping Channel. CoRR abs/2205.07663 (2022) - 2021
- [j9]Stephen DiAdamo, Janis Nötzel, Simon Sekavcnik, Riccardo Bassoli, Roberto Ferrara, Christian Deppe, Frank H. P. Fitzek, Holger Boche:
Integrating Quantum Simulation for Quantum-Enhanced Classical Network Emulation. IEEE Commun. Lett. 25(12): 3922-3926 (2021) - [c27]Andrea Cacioppo, Janis Nötzel, Matteo Rosati:
Compound Channel Capacities under Energy Constraints and Application. ISIT 2021: 640-645 - [i25]Stephen DiAdamo, Janis Nötzel:
Undoing Causal Effects of a Causal Broadcast Channel with Cooperating Receivers using Entanglement Resources. CoRR abs/2102.07427 (2021) - [i24]Andrea Cacioppo, Janis Nötzel, Matteo Rosati:
Compound Channel Capacities under Energy Constraints and Application. CoRR abs/2105.04274 (2021) - [i23]Stephen DiAdamo, Janis Nötzel, Simon Sekavcnik, Riccardo Bassoli, Roberto Ferrara, Christian Deppe, Frank H. P. Fitzek, Holger Boche:
Integrating Quantum Simulation for Quantum-Enhanced Classical Network Emulation. CoRR abs/2110.01437 (2021) - 2020
- [j8]Janis Noetzel:
Entanglement-Enabled Communication. IEEE J. Sel. Areas Inf. Theory 1(2): 401-415 (2020) - [c26]Janis Nötzel:
Entanglement-Enabled Communication. CITS 2020: 1-6 - [c25]Janis Nötzel, Stephen Diadamo:
Entanglement-Enabled Communication for the Internet of Things. CITS 2020: 1-6 - [c24]Janis Nötzel, Stephen Diadamo:
Entanglement-Assisted Data Transmission as an Enabling Technology: A Link-Layer Perspective. ISIT 2020: 1955-1960 - [c23]Janis Nötzel, Stephen DiAdamo:
Entanglement-Enhanced Communication Networks. QCE 2020: 242-248 - [i22]Stephen Diadamo, Janis Nötzel, Benjamin Zanger, Mehmet Mert Bese:
QuNetSim: A Software Framework for Quantum Networks. CoRR abs/2003.06397 (2020)
2010 – 2019
- 2019
- [j7]Christian Arendt, Janis Noetzel, Holger Boche:
Reliable Communication under the Influence of a State-Constrained Jammer: An Information-Theoretic Perspective on Receive Diversity. Probl. Inf. Transm. 55(2): 101-123 (2019) - [c22]Christian Arendt, Janis Nötzel, Holger Boche:
Reliable Communication Over Arbitrarily Varying Channels Under Block-Restricted Jamming. ICC 2019: 1-7 - [i21]Janis Nötzel:
Entanglement-Enabled Communication. CoRR abs/1910.03796 (2019) - 2018
- [c21]Janis Nötzel, Christian Arendt, Eduard Axel Jorswieck:
Analytical PARAFAC Decomposition with Application in Semi-Blind Diversity Detection. SAM 2018: 346-350 - [c20]Holger Boche, Christian Deppe, Janis Nötzel, Andreas J. Winter:
Fully Quantum Arbitrarily Varying Channels: Random Coding Capacity and Capacity Dichotomy. ISIT 2018: 2012-2016 - [c19]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Secret Message Transmission over Quantum Channels under Adversarial Quantum Noise: Secrecy Capacity and Super-activations. ITW 2018: 1-5 - [c18]Christian Arendt, Janis Nötzel, Holger Boche:
Evaluation of Distributed Post-Detection Receive Diversity Combining Schemes for Reliable Wireless Communication Over Arbitrarily Varying Channels. VTC Fall 2018: 1-6 - [i20]Holger Boche, Christian Deppe, Janis Nötzel, Andreas J. Winter:
Fully Quantum Arbitrarily Varying Channels: Random Coding Capacity and Capacity Dichotomy. CoRR abs/1801.04572 (2018) - [i19]Christian Arendt, Janis Nötzel, Holger Boche:
Ultra-Reliable Communication over Arbitrarily Varying Channels under Block-Restricted Jamming. CoRR abs/1805.09753 (2018) - 2017
- [j6]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Classical-quantum arbitrarily varying wiretap channel: common randomness assisted code and continuity. Quantum Inf. Process. 16(1): 35 (2017) - [c17]Robert Schmidt, Arash Toyser, Siddharth Naik, Janis Nötzel, Eduard A. Jorswieck:
Network Resource Trading: Locating the Contract Sweet Spot for the Case of Dynamic and Decentralized Non-broker Spectrum Sharing. CrownCom 2017: 3-14 - [c16]Christian Arendt, Janis Noetzel, Holger Boche:
Super-Activation of the Composite Independent Arbitrarily Varying Channel under State Constraints. GLOBECOM 2017: 1-6 - [c15]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Classical-quantum arbitrarily varying wiretap channel: Secret message transmission under jamming attacks. ISIT 2017: 1983-1987 - [c14]Janis Nötzel, Andreas J. Winter:
Information theoretic principles of universal discrete denoising. ISWCS 2017: 205-210 - [c13]Christian Arendt, Adrian Posselt, Peter Fertl, Janis Nötzel, Holger Boche:
Evaluation of vehicular antenna concepts under delay limited capacity as performance measure for safety critical message transfer. PIMRC 2017: 1-6 - [i18]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Classical-Quantum Arbitrarily Varying Wiretap Channel: Secret Message Transmission under Jamming Attacks. CoRR abs/1702.03483 (2017) - [i17]Janis Nötzel, Andreas J. Winter:
Information Theoretic Principles of Universal Discrete Denoising. CoRR abs/1705.08394 (2017) - [i16]Christian Arendt, Janis Nötzel, Holger Boche:
Reliable Communication under the Influence of a State-Constrained Jammer: A Novel Perspective on Receive Diversity. CoRR abs/1710.10811 (2017) - [i15]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Secret Message Transmission over Quantum Channels under Adversarial Quantum Noise: Secrecy Capacity and Super-Activation. CoRR abs/1712.05702 (2017) - 2016
- [j5]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Classical-quantum arbitrarily varying wiretap channel: Ahlswede dichotomy, positivity, resources, super-activation. Quantum Inf. Process. 15(11): 4853-4895 (2016) - [j4]Janis Nötzel, Moritz Wiese, Holger Boche:
The Arbitrarily Varying Wiretap Channel - Secret Randomness, Stability, and Super-Activation. IEEE Trans. Inf. Theory 62(6): 3504-3531 (2016) - [j3]Moritz Wiese, Janis Nötzel, Holger Boche:
A Channel Under Simultaneous Jamming and Eavesdropping Attack - Correlated Random Coding Capacities Under Strong Secrecy Criteria. IEEE Trans. Inf. Theory 62(7): 3844-3862 (2016) - [j2]Janis Noetzel, Walter Swetly:
Deducing Truth From Correlation. IEEE Trans. Inf. Theory 62(12): 7505-7517 (2016) - [c12]Janis Nötzel, Christian Arendt:
Using dependent component analysis for blind channel estimation in distributed antenna systems. GlobalSIP 2016: 1116-1121 - [c11]Holger Boche, Ning Cai, Janis Noetzel:
Classical-quantum channels with causal and non-causal channel state information at the sender. ISIT 2016: 2049-2053 - [c10]Holger Boche, Minglai Cai, Christian Deppe, Janis Noetzel:
Classical-quantum arbitrarily varying wiretap channel: Common randomness assisted code and continuity. ISIT 2016: 2059-2063 - [i14]Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel:
Classical - Quantum Arbitrarily Varying Wiretap Channel: Common Randomness Assisted Code and Continuity. CoRR abs/1606.01768 (2016) - 2015
- [c9]Carsten Rudolf Janda, Moritz Wiese, Janis Nötzel, Holger Boche, Eduard A. Jorswieck:
Wiretap-channels under constrained active and passive attacks. CNS 2015: 16-21 - [c8]Moritz Wiese, Janis Noetzel, Holger Boche:
The arbitrarily varying wiretap channel - communication under uncoordinated attacks. ISIT 2015: 2146-2150 - [c7]Janis Noetzel, Moritz Wiese, Holger Boche:
The arbitrarily varying wiretap channel - secret randomness, stability and super-activation. ISIT 2015: 2151-2155 - [i13]Janis Noetzel, Moritz Wiese, Holger Boche:
The Arbitrarily Varying Wiretap Channel - Secret Randomness, Stability and Super-Activation. CoRR abs/1501.07439 (2015) - [i12]Holger Boche, Ning Cai, Janis Nötzel:
The Classical-Quantum Channel with Random State Parameters Known to the Sender. CoRR abs/1506.06479 (2015) - 2014
- [j1]Holger Boche, Janis Nötzel:
The classical-quantum multiple access channel with conferencing encoders and with common messages. Quantum Inf. Process. 13(12): 2595-2617 (2014) - [c6]Holger Boche, Janis Nötzel:
Cooperation for the classical-quantum multiple access channel. ISIT 2014: 156-160 - [c5]Holger Boche, Janis Nötzel:
Positivity, discontinuity, finite resources, nonzero error for arbitrarily varying quantum channels. ISIT 2014: 541-545 - [i11]Holger Boche, Janis Nötzel:
Positivity, Discontinuity, Finite Resources and Nonzero Error for Arbitrarily Varying Quantum Channels. CoRR abs/1401.5360 (2014) - [i10]Moritz Wiese, Janis Nötzel, Holger Boche:
The Arbitrarily Varying Wiretap Channel - deterministic and correlated random coding capacities under the strong secrecy criterion. CoRR abs/1410.8078 (2014) - [i9]Janis Noetzel, Walter Swetly:
Telling Truth from Correlation. CoRR abs/1412.5831 (2014) - 2013
- [c4]Igor Bjelakovic, Holger Boche, Gisbert Janßen, Janis Nötzel:
Arbitrarily Varying and Compound Classical-Quantum Channels and a Note on Quantum Zero-Error Capacities. Information Theory, Combinatorics, and Search Theory 2013: 247-283 - [c3]Holger Boche, Janis Nötzel:
Arbitrarily small amounts of correlation for arbitrarily varying quantum channels. ISIT 2013: 734-738 - [i8]Holger Boche, Janis Noetzel:
Arbitrarily Small Amounts of Correlation for Arbitrarily Varying Quantum Channels. CoRR abs/1301.6063 (2013) - [i7]Janis Noetzel:
The depolarising channel and Horns problem. CoRR abs/1302.6262 (2013) - [i6]Holger Boche, Janis Noetzel:
The Classical-Quantum Multiple Access Channel with Conferencing Encoders and with Common Messages. CoRR abs/1310.1970 (2013) - [i5]Janis Nötzel:
Hypothesis Testing on Invariant Subspaces of the Symmetric Group, Part I - Quantum Sanov's Theorem and Arbitrarily Varying Sources. CoRR abs/1310.5553 (2013) - 2012
- [b1]Janis Nötzel:
Quantum communication under channel uncertainty. Technical University Munich, 2012, pp. 1-105 - [i4]Igor Bjelakovic, Holger Boche, Gisbert Janßen, Janis Nötzel:
Arbitrarily varying and compound classical-quantum channels and a note on quantum zero-error capacities. CoRR abs/1209.6325 (2012) - 2010
- [c2]Rudolf Ahlswede, Igor Bjelakovic, Holger Boche, Janis Noetzel:
Entanglement transmission over arbitrarily varying quantum channels. ISIT 2010: 2718-2722 - [i3]Rudolf Ahlswede, Igor Bjelakovic, Holger Boche, Janis Noetzel:
Entanglement Transmission over Arbitrarily Varying Quantum Channels. CoRR abs/1004.5551 (2010) - [i2]Rudolf Ahlswede, Igor Bjelakovic, Holger Boche, Janis Noetzel:
Quantum capacity under adversarial quantum noise: arbitrarily varying quantum channels. CoRR abs/1010.0418 (2010)
2000 – 2009
- 2009
- [c1]Igor Bjelakovic, Holger Boche, Janis Noetzel:
Entanglement transmission capacity of compound channels. ISIT 2009: 1889-1893 - 2008
- [i1]Igor Bjelakovic, Holger Boche, Janis Noetzel:
On Quantum Capacity of Compound Channels. CoRR abs/0808.1007 (2008)
Coauthor Index
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