default search action
Onur Dizdar
Person information
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
2020 – today
- 2024
- [j23]Onur Dizdar
, Ata Sattarzadeh
RSMA for Overloaded MIMO Networks: Low-Complexity Design for Max-Min Fairness. IEEE Trans. Wirel. Commun. 23(6): 6156-6173 (2024) - [j22]Rafael Cerna-Loli
Hybrid Automatic Repeat Request for Downlink Rate-Splitting Multiple Access. IEEE Trans. Wirel. Commun. 23(10): 15261-15275 (2024) - [j21]Onur Dizdar
Rate-Splitting Multiple Access for Semantic-Aware Networks: An Age of Incorrect Information Perspective. IEEE Wirel. Commun. Lett. 13(4): 1168-1172 (2024) - [j20]Fehmi Emre Kadan
Differential Sensing for Rank-Limited Communications. IEEE Wirel. Commun. Lett. 13(9): 2422-2426 (2024) - [i30]Ankit Gupta, Onur Dizdar, Yun Chen, Stephen Wang:
SpikingRx: From Neural to Spiking Receiver. CoRR abs/2409.05610 (2024) - 2023
- [j19]Jiawei Xu
Rate-Splitting Multiple Access for Short-Packet Uplink Communications: A Finite Blocklength Analysis. IEEE Commun. Lett. 27(2): 517-521 (2023) - [j18]Mehmet Mert Sahin
Multicarrier Rate-Splitting Multiple Access: Superiority of OFDM-RSMA Over OFDMA and OFDM-NOMA. IEEE Commun. Lett. 27(11): 3088-3092 (2023) - [j17]Sundar Aditya
Sensing Using Coded Communications Signals. IEEE Open J. Commun. Soc. 4: 134-152 (2023) - [j16]Yunnuo Xu
Max-Min Fairness of Rate-Splitting Multiple Access With Finite Blocklength Communications. IEEE Trans. Veh. Technol. 72(5): 6816-6821 (2023) - [j15]Rafael Cerna-Loli
Model-Based Deep Learning Receiver Design for Rate-Splitting Multiple Access. IEEE Trans. Wirel. Commun. 22(11): 8352-8365 (2023) - [c10]Sundar Aditya, Onur Dizdar, David Vargas, Bruno Clerckx
Rate Splitting Multiple Access: Prototypes, Experiments and Standardization Efforts. CSCN 2023: 376 - [c9]Yi Xien Yap, Neil Bhushan, Onur Dizdar, Ata Sattarzadeh, David Redgate, Venkateswara Battula, Stephen Wang:
A Proof of Concept for OTFS Resilience in Doubly-Selective Channels by GPU-Enabled Real-Time SDR. GLOBECOM 2023: 7206-7212 - [i29]Mehmet Mert Sahin, Onur Dizdar, Bruno Clerckx, Huseyin Arslan:
Multicarrier Rate-Splitting Multiple Access: Superiority of OFDM-RSMA over OFDMA and OFDM-NOMA. CoRR abs/2303.14540 (2023) - [i28]Rafael Cerna-Loli, Onur Dizdar, Bruno Clerckx, Petar Popovski:
Hybrid Automatic Repeat Request for Downlink Rate-Splitting Multiple Access. CoRR abs/2304.04320 (2023) - [i27]Onur Dizdar, Ata Sattarzadeh, Yi Xien Yap, Stephen Wang:
A Low-Complexity Design for Rate-Splitting Multiple Access in Overloaded MIMO Networks. CoRR abs/2306.13414 (2023) - [i26]Onur Dizdar, Ata Sattarzadeh, Yi Xien Yap, Stephen Wang:
RSMA for Overloaded MIMO Networks: Low-Complexity Design for Max-Min Fairness. CoRR abs/2306.13693 (2023) - [i25]Yi Xien Yap, Neil Bhushan, Onur Dizdar, Ata Sattarzadeh, David Redgate, Venkateswara Battula, Stephen Wang:
A Proof of Concept for OTFS Resilience in Doubly-Selective Channels by GPU-Enabled Real-Time SDR. CoRR abs/2309.12861 (2023) - [i24]Mehmet Mert Sahin, Onur Dizdar, Bruno Clerckx, Huseyin Arslan:
OFDM-RSMA: Robust Transmission under Inter-Carrier Interference. CoRR abs/2310.01686 (2023) - [i23]Onur Dizdar, Stephen Wang:
Rate-Splitting Multiple Access for Semantic-Aware Networks: an Age of Incorrect Information Perspective. CoRR abs/2312.07159 (2023) - 2022
- [j14]Yijie Mao
Rate-Splitting Multiple Access: Fundamentals, Survey, and Future Research Trends. IEEE Commun. Surv. Tutorials 24(4): 2073-2126 (2022) - [j13]Anup Mishra
Rate-Splitting Multiple Access for 6G - Part I: Principles, Applications and Future Works. IEEE Commun. Lett. 26(10): 2232-2236 (2022) - [j12]Longfei Yin
Rate-Splitting Multiple Access for 6G - Part II: Interplay With Integrated Sensing and Communications. IEEE Commun. Lett. 26(10): 2237-2241 (2022) - [j11]Hongyu Li
Rate-Splitting Multiple Access for 6G - Part III: Interplay With Reconfigurable Intelligent Surfaces. IEEE Commun. Lett. 26(10): 2242-2246 (2022) - [j10]Onur Dizdar
Energy Efficient Dual-Functional Radar-Communication: Rate-Splitting Multiple Access, Low-Resolution DACs, and RF Chain Selection. IEEE Open J. Commun. Soc. 3: 986-1006 (2022) - [j9]Anup Mishra
Rate-Splitting Multiple Access for Downlink Multiuser MIMO: Precoder Optimization and PHY-Layer Design. IEEE Trans. Commun. 70(2): 874-890 (2022) - [j8]Onur Dizdar
Rate-Splitting Multiple Access for Communications and Jamming in Multi-Antenna Multi-Carrier Cognitive Radio Systems. IEEE Trans. Inf. Forensics Secur. 17: 628-643 (2022) - [j7]Yunnuo Xu
Rate-Splitting Multiple Access With Finite Blocklength for Short-Packet and Low-Latency Downlink Communications. IEEE Trans. Veh. Technol. 71(11): 12333-12337 (2022) - [i22]Yijie Mao, Onur Dizdar, Bruno Clerckx, Robert Schober, Petar Popovski, H. Vincent Poor:
Rate-Splitting Multiple Access: Fundamentals, Survey, and Future Research Trends. CoRR abs/2201.03192 (2022) - [i21]Onur Dizdar, Aryan Kaushik, Bruno Clerckx, Christos Masouros:
Energy Efficient Dual-Functional Radar-Communication: Rate-Splitting Multiple Access, Low-Resolution DACs, and RF Chain Selection. CoRR abs/2202.09128 (2022) - [i20]Rafael Cerna-Loli, Onur Dizdar, Bruno Clerckx, Cong Ling:
Model-based Deep Learning Receiver Design for Rate-Splitting Multiple Access. CoRR abs/2205.00849 (2022) - [i19]Hongyu Li, Yijie Mao
Rate-Splitting Multiple Access for 6G - Part III: Interplay with Reconfigurable Intelligent Surfaces. CoRR abs/2205.02036 (2022) - [i18]Longfei Yin, Yijie Mao, Onur Dizdar, Bruno Clerckx:
Rate-Splitting Multiple Access for 6G - Part II: Interplay with Integrated Sensing and Communications. CoRR abs/2205.02462 (2022) - [i17]Anup Mishra, Yijie Mao
Rate-Splitting Multiple Access for 6G - Part I: Principles, Applications and Future Works. CoRR abs/2205.02548 (2022) - [i16]Yunnuo Xu, Yijie Mao
Max-Min Fairness of Rate-Splitting Multiple Access with Finite Blocklength Communications. CoRR abs/2207.05614 (2022) - [i15]Jiawei Xu, Onur Dizdar, Bruno Clerckx:
Rate-Splitting Multiple Access for Short-Packet Uplink Communications: A Finite Blocklength Error Probability Analysis. CoRR abs/2207.07782 (2022) - [i14]Sundar Aditya, Onur Dizdar, Bruno Clerckx, Xueru Li:
Sensing using Coded Communications Signals. CoRR abs/2209.04269 (2022) - 2021
- [j6]Onur Dizdar
Rate-Splitting Multiple Access to Mitigate the Curse of Mobility in (Massive) MIMO Networks. IEEE Trans. Commun. 69(10): 6765-6780 (2021) - [c8]Onur Dizdar
Rate-Splitting Multiple Access for Joint Radar-Communications with Low-Resolution DACs. ICC Workshops 2021: 1-6 - [c7]Longfei Yin, Onur Dizdar
Rate-Splitting Multiple Access for Multigroup Multicast Cellular and Satellite Communications: PHY Layer Design and Link-Level Simulations. ICC Workshops 2021: 1-6 - [c6]Onur Dizdar
Rate-Splitting Multiple Access for Enhanced URLLC and eMBB in 6G: Invited Paper. ISWCS 2021: 1-6 - [c5]Rafael Cerna-Loli, Onur Dizdar, Bruno Clerckx
A Rate-Splitting Strategy to Enable Joint Radar Sensing and Communication with Partial CSIT. SPAWC 2021: 491-495 - [i13]Onur Dizdar, Bruno Clerckx:
Rate Splitting Multiple Access for Multi-Antenna Multi-Carrier Joint Communications and Jamming. CoRR abs/2101.11318 (2021) - [i12]Onur Dizdar, Yijie Mao, Bruno Clerckx:
Rate-Splitting Multiple Access to Mitigate the Curse of Mobility in (Massive) MIMO Networks. CoRR abs/2102.06405 (2021) - [i11]Jihye An, Onur Dizdar, Bruno Clerckx, Wonjae Shin:
Rate-Splitting Multiple Access for Multi-Antenna Broadcast Channel with Imperfect CSIT and CSIR. CoRR abs/2102.08738 (2021) - [i10]Longfei Yin, Onur Dizdar, Bruno Clerckx:
Rate-Splitting Multiple Access for Multigroup Multicast Cellular and Satellite Communications: PHY Layer Design and Link-Level Simulations. CoRR abs/2104.00206 (2021) - [i9]Onur Dizdar, Yijie Mao, Yunnuo Xu, Peiying Zhu, Bruno Clerckx:
Rate-Splitting Multiple Access for Enhanced URLLC and eMBB in 6G. CoRR abs/2105.00442 (2021) - [i8]Rafael Cerna-Loli, Onur Dizdar, Bruno Clerckx:
A Rate-Splitting Strategy to Enable Joint Radar Sensing and Communication with Partial CSIT. CoRR abs/2105.00633 (2021) - [i7]Yunnuo Xu, Yijie Mao, Onur Dizdar, Bruno Clerckx:
Rate-Splitting Multiple Access with Finite Blocklength for Short-Packet and Low-Latency Downlink Communications. CoRR abs/2105.06198 (2021) - [i6]Anup Mishra, Yijie Mao, Onur Dizdar, Bruno Clerckx:
Rate-Splitting Multiple Access for Downlink Multiuser MIMO: Precoder Optimization and PHY-Layer Design. CoRR abs/2105.07362 (2021) - [i5]Onur Dizdar, Bruno Clerckx:
Rate-Splitting Multiple Access for Communications and Jamming in Multi-Antenna Multi-Carrier Cognitive Radio Systems. CoRR abs/2107.05256 (2021) - 2020
- [j5]Onur Dizdar
A Complexity Reduction Method for Successive Cancellation List Decoding. IEEE Trans. Circuits Syst. II Express Briefs 67-II(4): 655-659 (2020) - [c4]Onur Dizdar
Rate-Splitting Multiple Access for Downlink Multi-Antenna Communications: Physical Layer Design and Link-level Simulations. PIMRC 2020: 1-6 - [c3]Onur Dizdar
Rate-Splitting Multiple Access: A New Frontier for the PHY Layer of 6G. VTC Fall 2020: 1-7 - [i4]Onur Dizdar, Yijie Mao, Wei Han, Bruno Clerckx:
Rate-Splitting Multiple Access for Downlink Multi-Antenna Communications: Physical Layer Design and Link-level Simulations. CoRR abs/2005.13257 (2020) - [i3]Onur Dizdar, Yijie Mao, Wei Han, Bruno Clerckx:
Rate-Splitting Multiple Access: A New Frontier for the PHY Layer of 6G. CoRR abs/2006.01437 (2020)
2010 – 2019
- 2019
- [j4]Onur Dizdar
An Uplink Non-Orthogonal Multiple Access Method Based on Frozen Bit Patterns of Polar Codes. IEEE Commun. Lett. 23(6): 975-978 (2019) - [j3]Evren Çatak, Ferdi Tekçe
Multi-user shared access in massive machine-type communication systems via superimposed waveforms. Phys. Commun. 37 (2019) - [c2]Çagri Göken, Onur Dizdar
Filtering for Uplink Non-Orthogonal Multiple Access with Imperfect Received Power Control. PIMRC 2019: 1-6 - 2018
- [i2]Onur Dizdar:
A Complexity Reduction Method for Successive Cancellation List Decoding. CoRR abs/1812.09357 (2018) - 2017
- [c1]Çagri Göken, Onur Dizdar
Performance of edge windowing for OFDM under non-linear power amplifier effects. MILCOM 2017: 219-224 - 2016
- [j2]Onur Dizdar
A High-Throughput Energy-Efficient Implementation of Successive Cancellation Decoder for Polar Codes Using Combinational Logic. IEEE Trans. Circuits Syst. I Regul. Pap. 63-I(3): 436-447 (2016) - 2014
- [i1]Onur Dizdar, Erdal Arikan:
A High-Throughput Energy-Efficient Implementation of Successive-Cancellation Decoder for Polar Codes Using Combinational Logic. CoRR abs/1412.3829 (2014) - 2012
- [j1]Onur Dizdar
Blind Channel Estimation Based on the Lloyd-Max Algorithm in Narrowband Fading Channels and Partial-Band Jamming. IEEE Trans. Commun. 60(7): 1986-1995 (2012)
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 2024-11-07 20:22 CET 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: