default search action
Alexander Jung
Person information
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
2020 – today
- 2024
- [j30]Stefan Hessel, Alexander Jung:
Datenschutzrechtliche Herausforderungen bei der Verwertung von Daten vernetzter Medizinprodukte. Datenschutz und Datensicherheit (dud) 48(5): 289-294 (2024) - [j29]Linli Zhang, Georgios Karakasidis, Arina Odnoblyudova, Leyla Dogruel, Yu Tian, Alex Jung:
Explainable empirical risk minimization. Neural Comput. Appl. 36(8): 3983-3996 (2024) - [j28]Jun Yang, Pia Fricker, Alexander Jung:
From intangible to tangible: The role of big data and machine learning in walkability studies. Comput. Environ. Urban Syst. 109: 102087 (2024) - [c45]Alexander Jung, Helge Parzyjegla, Peter Danielis:
Opportunistic Protocols for People Counting in Dynamic Networks. CCNC 2024: 198-201 - [c44]Alexander Jung:
Analysis of Total Variation Minimization for Clustered Federated Learning. EUSIPCO 2024: 1027-1031 - [i50]Christophe Nicolet, Antoine Béguin, Matthieu Dreyer, Sébastien Alligné, Alexander Jung, Diogo Cordeiro, Carlos Moreira:
Inertia emulation contribution of Frades 2 variable speed pump-turbine to power network stability. CoRR abs/2404.06299 (2024) - [i49]Alexander Jung, Yasmin Sarcheshmehpour, Amirhossein Mohammadi:
Personalized Federated Learning via Active Sampling. CoRR abs/2409.02064 (2024) - [i48]Diana Pfau, Alexander Jung:
Engineering Trustworthy AI: A Developer Guide for Empirical Risk Minimization. CoRR abs/2410.19361 (2024) - 2023
- [j27]Argyrios Petras, Matthias A. F. Gsell, Christoph M. Augustin, Jairo Rodríguez-Padilla, Alexander Jung, Marina Strocchi, Frits W. Prinzen, Steven A. Niederer, Gernot Plank, Edward J. Vigmond:
Mechanoelectric effects in healthy cardiac function and under Left Bundle Branch Block pathology. Comput. Biol. Medicine 156: 106696 (2023) - [j26]Moloud Abdar, Mohammad Amin Fahami, Leonardo Rundo, Petia Radeva, Alejandro F. Frangi, U. Rajendra Acharya, Abbas Khosravi, Hak-Keung Lam, Alexander Jung, Saeid Nahavandi:
Hercules: Deep Hierarchical Attentive Multilevel Fusion Model With Uncertainty Quantification for Medical Image Classification. IEEE Trans. Ind. Informatics 19(1): 274-285 (2023) - [j25]Yasmin Sarcheshmehpour, Yu Tian, Linli Zhang, Alexander Jung:
Clustered Federated Learning via Generalized Total Variation Minimization. IEEE Trans. Signal Process. 71: 4240-4256 (2023) - [c43]Reza Mirzaeifard, Naveen K. D. Venkategowda, Alexander Jung, Stefan Werner:
Moreau Envelope ADMM for Decentralized Weakly Convex Optimization. APSIPA ASC 2023: 1126-1130 - [c42]Alexander Jung, S. Abdurakhmanova, Olga Kuznetsova, Yasmin Sarcheshmehpour:
Towards Model-Agnostic Federated Learning over Networks. EUSIPCO 2023: 1614-1618 - [i47]Xu Yang, Yu Tian, Irene Schicker, Alexander Jung:
Wind to start the washing machine? High-Resolution Wind Atlas for Finland. CoRR abs/2303.04403 (2023) - [i46]Yasmin Sarcheshmehpour, Tommi Ryyppo, Victor Mukherjee, Alex Jung:
Design of Induction Machines using Reinforcement Learning. CoRR abs/2306.17626 (2023) - [i45]Reza Mirzaeifard, Naveen K. D. Venkategowda, Alexander Jung, Stefan Werner:
Moreau Envelope ADMM for Decentralized Weakly Convex Optimization. CoRR abs/2308.16752 (2023) - 2022
- [b1]Alexander Jung:
Machine Learning - The Basics. Springer 2022, ISBN 978-981-16-8192-9, pp. 1-200 - [j24]Jinping Sui, Zhen Liu, Li Liu, Alexander Jung, Xiang Li:
Dynamic Sparse Subspace Clustering for Evolving High-Dimensional Data Streams. IEEE Trans. Cybern. 52(6): 4173-4186 (2022) - [c41]Hugo Lefeuvre, Vlad-Andrei Badoiu, Alexander Jung, Stefan Lucian Teodorescu, Sebastian Rauch, Felipe Huici, Costin Raiciu, Pierre Olivier:
FlexOS: towards flexible OS isolation. ASPLOS 2022: 467-482 - [i44]Yasmin Sarcheshmehpour, Yu Tian, Linli Zhang, Alexander Jung:
flow-based clustering and spectral clustering: a comparison. CoRR abs/2206.10019 (2022) - 2021
- [j23]Alexander Jung, Yasmin Sarcheshmehpour:
Local Graph Clustering With Network Lasso. IEEE Signal Process. Lett. 28: 106-110 (2021) - [c40]Yasmin Sarcheshmehpour, Yu Tian, Linli Zhang, Alexander Jung:
Flow-Based Clustering and Spectral Clustering: A Comparison. ACSCC 2021: 1292-1296 - [c39]Alexander Jung, Hugo Lefeuvre, Charalampos Rotsos, Pierre Olivier, Daniel Oñoro-Rubio, Felipe Huici, Mathias Niepert:
Wayfinder: towards automatically deriving optimal OS configurations. APSys 2021: 115-122 - [c38]Simon Kuenzer, Vlad-Andrei Badoiu, Hugo Lefeuvre, Sharan Santhanam, Alexander Jung, Gaulthier Gain, Cyril Soldani, Costin Lupu, Stefan Teodorescu, Costi Raducanu, Cristian Banu, Laurent Mathy, Razvan Deaconescu, Costin Raiciu, Felipe Huici:
Unikraft: fast, specialized unikernels the easy way. EuroSys 2021: 376-394 - [c37]Yasmin Sarcheshmehpour, M. Leinonen, Alexander Jung:
Federated Learning from Big Data Over Networks. ICASSP 2021: 3055-3059 - [i43]Simon Kuenzer, Vlad-Andrei Badoiu, Hugo Lefeuvre, Sharan Santhanam, Alexander Jung, Gaulthier Gain, Cyril Soldani, Costin Lupu, Stefan Teodorescu, Costi Raducanu, Cristian Banu, Laurent Mathy, Razvan Deaconescu, Costin Raiciu, Felipe Huici:
Unikraft: Fast, Specialized Unikernels the Easy Way. CoRR abs/2104.12721 (2021) - [i42]Yasmin Sarcheshmehpour, Yu Tian, Linli Zhang, Alexander Jung:
Networked Federated Multi-Task Learning. CoRR abs/2105.12769 (2021) - [i41]Pasi Pyrrö, Hassan Naseri, Alexander Jung:
Rethinking Drone-Based Search and Rescue with Aerial Person Detection. CoRR abs/2111.09406 (2021) - [i40]Hugo Lefeuvre, Vlad-Andrei Badoiu, Alexander Jung, Stefan Teodorescu, Sebastian Rauch, Felipe Huici, Costin Raiciu, Pierre Olivier:
FlexOS: Towards Flexible OS Isolation. CoRR abs/2112.06566 (2021) - 2020
- [j22]Alexander Jung:
Networked Exponential Families for Big Data Over Networks. IEEE Access 8: 202897-202909 (2020) - [j21]Henrik E. C. Cao, Riku Sarlin, Alexander Jung:
Learning Explainable Decision Rules via Maximum Satisfiability. IEEE Access 8: 218180-218185 (2020) - [j20]Alexander Jung, Pedro H. J. Nardelli:
An Information-Theoretic Approach to Personalized Explainable Machine Learning. IEEE Signal Process. Lett. 27: 825-829 (2020) - [j19]Alexander Jung:
On the Duality Between Network Flows and Network Lasso. IEEE Signal Process. Lett. 27: 940-944 (2020) - [j18]Nguyen Q. Tran, Oleksii Abramenko, Alexander Jung:
On the Sample Complexity of Graphical Model Selection From Non-Stationary Samples. IEEE Trans. Signal Process. 68: 17-32 (2020) - [c36]Alexander Jung:
Clustering in Partially Labeled Stochastic Block Models via Total Variation Minimization. ACSSC 2020: 731-735 - [c35]Sharan Santhanam, Simon Kuenzer, Hugo Lefeuvre, Felipe Huici, Alexander Jung, Santiago Pagani, George-Cristian Muraru, Stefano Stabellini, Justin He, Jonathan Beri:
Towards Highly Specialized, POSIX -compliant Software Stacks with Unikraft: Work-in-Progress. EMSOFT 2020: 31-33 - [c34]Timo Huuhtanen, Antti Lankinen, Alexander Jung:
Target Tracking on Sensing Surface with Electrical Impedance Tomography. EUSIPCO 2020: 1817-1821 - [c33]Nguyen Q. Tran, Henrik Ambos, Alexander Jung:
Classifying Partially Labeled Networked Data VIA Logistic Network Lasso. ICASSP 2020: 3832-3836 - [c32]Timo Huuhtanen, Alexander Jung:
Anomaly Location Detection with Electrical Impedance Tomography Using Multilayer Perceptrons. MLSP 2020: 1-6 - [i39]Alexander Jung, Pedro H. J. Nardelli:
An Information-Theoretic Approach to Personalized Explainable Machine Learning. CoRR abs/2003.00484 (2020) - [i38]Alexander Jung:
Local Graph Clustering with Network Lasso. CoRR abs/2004.12199 (2020) - [i37]Alexander Jung:
Explainable Empirical Risk Minimization. CoRR abs/2009.01492 (2020) - [i36]Dick Carrillo, Lam Duc Nguyen, Pedro H. J. Nardelli, Evangelos Pournaras, Plinio P. Morita, Demóstenes Z. Rodríguez, Merim Dzaferagic, Harun Siljak, Alexander Jung, Laurent Hébert-Dufresne, Irene Macaluso, Mehar Ullah, Gustavo Fraidenraich, Petar Popovski:
Containing Future Epidemics with Trustworthy Federated Systems for Ubiquitous Warning and Response. CoRR abs/2010.13392 (2020) - [i35]Yasmin Sarcheshmehpour, M. Leinonen, Alexander Jung:
Federated Learning From Big Data Over Networks. CoRR abs/2010.14159 (2020)
2010 – 2019
- 2019
- [j17]Menghao Wu, Yanbin Gao, Alexander Jung, Qiang Zhang, Shitong Du:
The Actor-Dueling-Critic Method for Reinforcement Learning. Sensors 19(7): 1547 (2019) - [j16]Alexander Jung, Nguyen Q. Tran:
Localized Linear Regression in Networked Data. IEEE Signal Process. Lett. 26(7): 1090-1094 (2019) - [j15]Roope Tervo, Joonas Karjalainen, Alexander Jung:
Short-Term Prediction of Electricity Outages Caused by Convective Storms. IEEE Trans. Geosci. Remote. Sens. 57(11): 8618-8626 (2019) - [j14]Alexander Jung, Alfred O. Hero III, Alexandru Mara, Saeed Jahromi, Ayelet Heimowitz, Yonina C. Eldar:
Semi-Supervised Learning in Network-Structured Data via Total Variation Minimization. IEEE Trans. Signal Process. 67(24): 6256-6269 (2019) - [c31]Alexander Jung, Natalia Vesselinova:
Analysis of Network Lasso for Semi-Supervised Regression. AISTATS 2019: 380-387 - [c30]Timo Huuhtanen, Henrik Ambos, Alexander Jung:
Outlier Detection from Non-Smooth Sensor Data. EUSIPCO 2019: 1-5 - [c29]Vladimir Herdt, Daniel Große, Rolf Drechsler, Christoph Gerum, Alexander Jung, Joscha Benz, Oliver Bringmann, Michael Schwarz, Dominik Stoffel, Wolfgang Kunz:
Systematic RISC-V based Firmware Design⋆. FDL 2019: 1-8 - [c28]Oleksii Abramenko, Alexander Jung:
Graph Signal Sampling via Reinforcement Learning. ICASSP 2019: 3077-3081 - [c27]Jinping Sui, Zhen Liu, Li Liu, Alexander Jung, Tianpeng Liu, Bo Peng, Xiang Li:
Sparse Subspace Clustering for Evolving Data Streams. ICASSP 2019: 7455-7459 - [c26]Julen Kahles, Juha Torronen, Timo Huuhtanen, Alexander Jung:
Automating Root Cause Analysis via Machine Learning in Agile Software Testing Environments. ICST 2019: 379-390 - [i34]Alexander Jung, Alfred O. Hero III, Alexandru Mara, Saeed Jahromi, Ayelet Heimowitz, Yonina C. Eldar:
Semi-supervised Learning in Network-Structured Data via Total Variation Minimization. CoRR abs/1901.09838 (2019) - [i33]Nguyen Q. Tran, Henrik Ambos, Alexander Jung:
Classifying Partially Labeled Networked Data via Logistic Network Lasso. CoRR abs/1903.10926 (2019) - [i32]Alexander Jung, Nguyen Q. Tran:
Localized Linear Regression in Networked Data. CoRR abs/1903.11178 (2019) - [i31]Alexander Jung:
Learning Networked Exponential Families with Network Lasso. CoRR abs/1905.09056 (2019) - [i30]Roope Tervo, Joonas Karjalainen, Alexander Jung:
Short-term prediction of Electricity Outages Caused by Convective Storms. CoRR abs/1907.00662 (2019) - [i29]Alexander Jung:
On the Duality between Network Flows and Network Lasso. CoRR abs/1910.01805 (2019) - [i28]Alexander Jung:
Components of Machine Learning: Binding Bits and FLOPS. CoRR abs/1910.12387 (2019) - [i27]Alexander Jung:
Clustering in Partially Labeled Stochastic Block Models via Total Variation Minimization. CoRR abs/1911.00958 (2019) - [i26]Alexander Jung, Ivan Baranov:
Basic Principles of Clustering Methods. CoRR abs/1911.07891 (2019) - 2018
- [j13]Jinping Sui, Zhen Liu, Alexander Jung, Li Liu, Xiang Li:
Dynamic Clustering Scheme for Evolving Data Streams Based on Improved STRAP. IEEE Access 6: 46157-46166 (2018) - [j12]Alexander Jung, Madelon Hulsebos:
The Network Nullspace Property for Compressed Sensing of Big Data Over Networks. Frontiers Appl. Math. Stat. 4: 9 (2018) - [j11]Alexander Jung:
On the Complexity of Sparse Label Propagation. Frontiers Appl. Math. Stat. 4: 22 (2018) - [c25]Henrik Ambos, Nguyen Q. Tran, Alexander Jung:
Classifying Big Data Over Networks Via The Logistic Network Lasso. ACSSC 2018: 855-858 - [c24]Markku Hinkka, Teemu Lehto, Keijo Heljanko, Alexander Jung:
Classifying Process Instances Using Recurrent Neural Networks. Business Process Management Workshops 2018: 313-324 - [c23]Timo Huuhtanen, Alexander Jung:
Predictive Maintenance of Photovoltaic Panels via Deep Learning. DSW 2018: 66-70 - [c22]Roope Tervo, Joonas Karjalainen, Alexander Jung:
Predicting Electricity Outages Caused By Convective Storms. DSW 2018: 145-149 - [c21]Madelon Hulsebos, Alexander Jung:
The Network Nullspace Property for Compressed Sensing of Big Data Over Networks. ICASSP 2018: 4549-4553 - [c20]Nguyen Q. Tran, Alexander Jung:
On the Sample Complexity of Graphical Model Selection from Non-Stationary Samples. ICASSP 2018: 6314-6317 - [c19]Nguyen Q. Tran, Henrik Ambos, Alexander Jung:
A Network Compatibility Condition For Compressed Sensing Over Complex Networks. SSP 2018: 50-54 - [c18]Buse Gul Atli, Yoan Miche, Alexander Jung:
Network Intrusion Detection Using Flow Statistics. SSP 2018: 70-74 - [i25]Buse Gul Atli, Alexander Jung:
Online Feature Ranking for Intrusion Detection Systems. CoRR abs/1803.00530 (2018) - [i24]Alexander Jung:
On The Complexity of Sparse Label Propagation. CoRR abs/1804.09597 (2018) - [i23]Henrik Ambos, Nguyen Q. Tran, Alexander Jung:
The Logistic Network Lasso. CoRR abs/1805.02483 (2018) - [i22]Alexander Jung:
A Gentle Introduction to Supervised Machine Learning. CoRR abs/1805.05052 (2018) - [i21]Oleksii Abramenko, Alexander Jung:
Graph Signal Sampling via Reinforcement Learning. CoRR abs/1805.05827 (2018) - [i20]Roope Tervo, Joonas Karjalainen, Alexander Jung:
Predicting Electricity Outages Caused by Convective Storms. CoRR abs/1805.07897 (2018) - [i19]Alexander Jung:
Analysis of Network Lasso For Semi-Supervised Regression. CoRR abs/1808.07249 (2018) - [i18]Markku Hinkka, Teemu Lehto, Keijo Heljanko, Alexander Jung:
Classifying Process Instances Using Recurrent Neural Networks. CoRR abs/1809.05896 (2018) - 2017
- [j10]Alexander Jung:
A Fixed-Point of View on Gradient Methods for Big Data. Frontiers Appl. Math. Stat. 3: 18 (2017) - [j9]Alexander Jung, Nguyen Tran Quang, Alexandru Mara:
When Is Network Lasso Accurate? Frontiers Appl. Math. Stat. 3: 28 (2017) - [c17]Alexandru Mara, Alexander Jung:
Recovery conditions and sampling strategies for network Lasso. ACSSC 2017: 405-409 - [c16]Luiza Sayfullina, Eric Malmi, Yiping Liao, Alexander Jung:
Domain Adaptation for Resume Classification Using Convolutional Neural Networks. AIST 2017: 82-93 - [c15]Markku Hinkka, Teemu Lehto, Keijo Heljanko, Alexander Jung:
Structural Feature Selection for Event Logs. Business Process Management Workshops 2017: 20-35 - [c14]Florian Roemer, Marcus Grossmann, Tobias Schoen, Roland Gruber, Alexander Jung, Steven Oeckl, Giovanni Del Galdo:
Differential SART for sub-Nyquist tomographic reconstruction in presence of misalignments. EUSIPCO 2017: 2354-2358 - [c13]Gita Babazadeh Eslamlou, Alexander Jung, Norbert Goertz:
Smooth graph signal recovery via efficient Laplacian solvers. ICASSP 2017: 5915-5919 - [c12]Nguyen Tran Quang, Alexander Jung:
Learning conditional independence structure for high-dimensional uncorrelated vector processes. ICASSP 2017: 5920-5924 - [i17]Nguyen Tran Quang, Alexander Jung:
On the Sample Complexity of Graphical Model Selection for Non-Stationary Processes. CoRR abs/1701.04724 (2017) - [i16]Saeed Basirian, Alexander Jung:
Random Walk Sampling for Big Data over Networks. CoRR abs/1704.04799 (2017) - [i15]Alexander Jung:
The Network Nullspace Property for Compressed Sensing of Big Data over Networks. CoRR abs/1705.04379 (2017) - [i14]Luiza Sayfullina, Eric Malmi, Yiping Liao, Alex Jung:
Domain Adaptation for Resume Classification Using Convolutional Neural Networks. CoRR abs/1707.05576 (2017) - [i13]Alexandru Mara, Alexander Jung:
Recovery Conditions and Sampling Strategies for Network Lasso. CoRR abs/1709.01402 (2017) - [i12]Markku Hinkka, Teemu Lehto, Keijo Heljanko, Alexander Jung:
Structural Feature Selection for Event Logs. CoRR abs/1710.02823 (2017) - [i11]Nguyen Q. Tran, Saeed Basirian, Alexander Jung:
When is Network Lasso Accurate: The Vector Case. CoRR abs/1710.03942 (2017) - 2016
- [j8]Alexander Jung, Yonina C. Eldar, Norbert Goertz:
On the Minimax Risk of Dictionary Learning. IEEE Trans. Inf. Theory 62(3): 1501-1515 (2016) - [c11]Gabor Hannak, Peter Berger, Gerald Matz, Alexander Jung:
Efficient graph signal recovery over big networks. ACSSC 2016: 1839-1843 - [c10]Gita Babazadeh Eslamlou, Alexander Jung, Norbert Goertz, Mehdi Fereydooni:
Graph signal recovery from incomplete and noisy information using approximate message passing. ICASSP 2016: 6170-6174 - [c9]Alexander Jung, Peter Berger, Gabor Hannak, Gerald Matz:
Scalable graph signal recovery for big data over networks. SPAWC 2016: 1-6 - [i10]Nguyen Tran Quang, Alexander Jung:
Learning conditional independence structure for high-dimensional uncorrelated vector processes. CoRR abs/1609.03772 (2016) - [i9]Wissem Inoubli, Sabeur Aridhi, Haithem Mezni, Alexander Jung:
Big Data Frameworks: A Comparative Study. CoRR abs/1610.09962 (2016) - [i8]Alexander Jung, Alfred O. Hero III, Alexandru Mara, Sabeur Aridhi:
Scalable Semi-Supervised Learning over Networks using Nonsmooth Convex Optimization. CoRR abs/1611.00714 (2016) - [i7]Alexander Jung:
Sparse Label Propagation. CoRR abs/1612.01414 (2016) - 2015
- [j7]Alexander Jung, Gabor Hannak, Norbert Goertz:
Graphical LASSO based Model Selection for Time Series. IEEE Signal Process. Lett. 22(10): 1781-1785 (2015) - [j6]Alexander Jung:
Learning the Conditional Independence Structure of Stationary Time Series: A Multitask Learning Approach. IEEE Trans. Signal Process. 63(21): 5677-5690 (2015) - [c8]Gabor Hannak, Martin Mayer, Alexander Jung, Gerald Matz, Norbert Goertz:
Joint channel estimation and activity detection for multiuser communication systems. ICC Workshops 2015: 2086-2091 - [i6]Alexander Jung, Yonina C. Eldar, Norbert Görtz:
On the Minimax Risk of Dictionary Learning. CoRR abs/1507.05498 (2015) - 2014
- [j5]Norbert Goertz, Chunli Guo, Alexander Jung, Mike E. Davies, Gerhard Doblinger:
Iterative Recovery of Dense Signals from Incomplete Measurements. IEEE Signal Process. Lett. 21(9): 1059-1063 (2014) - [j4]Alexander Jung, Sebastian Schmutzhard, Franz Hlawatsch:
The RKHS Approach to Minimum Variance Estimation Revisited: Variance Bounds, Sufficient Statistics, and Exponential Families. IEEE Trans. Inf. Theory 60(7): 4050-4065 (2014) - [j3]Alexander Jung, Sebastian Schmutzhard, Franz Hlawatsch, Zvika Ben-Haim, Yonina C. Eldar:
Minimum Variance Estimation of a Sparse Vector Within the Linear Gaussian Model: An RKHS Approach. IEEE Trans. Inf. Theory 60(10): 6555-6575 (2014) - [c7]Gabor Hannak, Alexander Jung, Norbert Goertz:
On the information-theoretic limits of graphical model selection for Gaussian time series. EUSIPCO 2014: 516-520 - [c6]Alexander Jung, Yonina C. Eldar, Norbert Goertz:
Performance limits of dictionary learning for sparse coding. EUSIPCO 2014: 765-769 - [c5]Alexander Jung, Reinhard Heckel, Helmut Bölcskei, Franz Hlawatsch:
Compressive nonparametric graphical model selection for time series. ICASSP 2014: 769-773 - 2013
- [j2]Alexander Jung, Georg Tauböck, Franz Hlawatsch:
Compressive Spectral Estimation for Nonstationary Random Processes. IEEE Trans. Inf. Theory 59(5): 3117-3138 (2013) - [i5]Alexander Jung, Sebastian Schmutzhard, Franz Hlawatsch, Zvika Ben-Haim, Yonina C. Eldar:
Minimum Variance Estimation of a Sparse Vector within the Linear Gaussian Model: An RKHS Approach. CoRR abs/1304.3886 (2013) - 2011
- [j1]Alexander Jung, Zvika Ben-Haim, Franz Hlawatsch, Yonina C. Eldar:
Unbiased Estimation of a Sparse Vector in White Gaussian Noise. IEEE Trans. Inf. Theory 57(12): 7856-7876 (2011) - [c4]Alexander Jung, Sebastian Schmutzhard, Franz Hlawatsch, Alfred O. Hero III:
Performance bounds for sparse parametric covariance estimation in Gaussian models. ICASSP 2011: 4156-4159 - [c3]Sebastian Schmutzhard, Alexander Jung, Franz Hlawatsch:
Minimum variance estimation for the sparse signal in noise model. ISIT 2011: 124-128 - [i4]Alexander Jung, Sebastian Schmutzhard, Franz Hlawatsch, Alfred O. Hero III:
Performance Bounds for Sparse Parametric Covariance Estimation in Gaussian Models. CoRR abs/1101.3838 (2011) - 2010
- [c2]Alexander Jung, Zvika Ben-Haim, Franz Hlawatsch, Yonina C. Eldar:
On unbiased estimation of sparse vectors corrupted by Gaussian noise. ICASSP 2010: 3990-3993 - [i3]Alexander Jung, Zvika Ben-Haim, Franz Hlawatsch, Yonina C. Eldar:
On Unbiased Estimation of Sparse Vectors Corrupted by Gaussian Noise. CoRR abs/1002.0110 (2010) - [i2]Alexander Jung, Zvika Ben-Haim, Franz Hlawatsch, Yonina C. Eldar:
Unbiased Estimation of a Sparse Vector in White Gaussian Noise. CoRR abs/1005.5697 (2010) - [i1]Sebastian Schmutzhard, Alexander Jung, Franz Hlawatsch, Zvika Ben-Haim, Yonina C. Eldar:
A Lower Bound on the Estimator Variance for the Sparse Linear Model. CoRR abs/1009.3353 (2010)
2000 – 2009
- 2009
- [c1]Alexander Jung, Georg Tauböck, Franz Hlawatsch:
Compressive spectral estimation for nonstationary random processes. ICASSP 2009: 3029-3032
Coauthor Index
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 2024-11-30 01:13 CET by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint