default search action
Google
Google Scholar
Semantic Scholar
Internet Archive Scholar
CiteSeerX
ORCIDDavid W. Matolak
David Matolak
Person information
- affiliation: University of South Carolina, Department of Electrical Engineering, Columbia, SC, USA
- affiliation: Ohio University, School of Electrical Engineering and Computer Science, Athens, OH, USA
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
showing all ?? records
2020 – today
- 2024
[j77]Zeenat Afroze
, David W. Matolak:
LOS-to-NLOS Channel Transition Measurements, Analysis and Characterization for the 90 GHz Band. IEEE Trans. Veh. Technol. 73(5): 6073-6082 (2024)- [j76]Zeenat Afroze, David W. Matolak:
Channel Characterization for the 90 GHz Band in Aviation Environments. IEEE Trans. Wirel. Commun. 23(10): 14249-14258 (2024) - 2023
- [j75]Marnie K. McLean, R. Glenn Weaver, Abbi Lane, Michal T. Smith, Hannah Parker, Ben Stone, Jonas McAninch, David W. Matolak, Sarah Burkart, M. V. S. Chandrashekhar, Bridget Armstrong:
A Sliding Scale Signal Quality Metric of Photoplethysmography Applicable to Measuring Heart Rate across Clinical Contexts with Chest Mounting as a Case Study. Sensors 23(7): 3429 (2023) - 2022
- [j74]Jinwen Liu, David W. Matolak, Ismail Güvenç, Hani Mehrpouyan:
Tropospheric attenuation prediction for future millimeter wave terrestrial systems: Estimating statistics and extremes. Int. J. Commun. Syst. 35(13) (2022) - [j73]Kamesh Namuduri, Uwe-Carsten Fiebig, David W. Matolak, Ismail Güvenç, K. V. S. Hari, Helka-Liina Määttänen:
Advanced Air Mobility: Research Directions for Communications, Navigation, and Surveillance. IEEE Veh. Technol. Mag. 17(4): 65-73 (2022) - [c62]Zeenat Afroze, David W. Matolak, Hudson Dye:
Indoor and Outdoor 90 GHz LOS-to-NLOS Channel Transition Characteristics. WCNC 2022: 938-943 - 2021
- [j72]Alphan Sahin, Nozhan Hosseini, Hosseinali Jamal, Safi Shams Muhtasimul Hoque, David W. Matolak:
DFT-Spread-OFDM-Based Chirp Transmission. IEEE Commun. Lett. 25(3): 902-906 (2021) - [j71]Nozhan Hosseini, David W. Matolak:
Nonlinear Quasi-Synchronous Multi User Chirp Spread Spectrum Signaling. IEEE Trans. Commun. 69(5): 3079-3090 (2021) - [j70]Nozhan Hosseini, David W. Matolak:
Noncoherent Multiuser Chirp Spread Spectrum: Performance With Doppler Shift and Asynchronism. IEEE Trans. Commun. 69(7): 4558-4568 (2021) - [j69]Hosseinali Jamal, David W. Matolak:
Multicarrier Spectral Shaping for Non-White Interference Channels: Application to Aeronautical Communications in the L-Band. IEEE Trans. Veh. Technol. 70(10): 10686-10694 (2021) - [j68]Kamesh Namuduri, Uwe-Carsten Fiebig, K. V. S. Hari, David W. Matolak, Ismail Güvenç, Helka-Liina Määttänen:
Advanced Air Mobility [From the Guest Editors]. IEEE Veh. Technol. Mag. 16(3): 87-164 (2021) - [c61]Zeenat Afroze, Mohanad Mohsen, David W. Matolak, Hudson Dye:
Indoor 90 GHz Channel Measurement Results for LOS to NLOS Transitions. MILCOM 2021: 402-407 - 2020
- [j67]Ke Guan, Markus Rupp, Thomas Kürner, César Briso, David W. Matolak, Jun-ichi Takada, Wei Wang:
IEEE Access Special Section Editorial: 5G and Beyond Mobile Wireless Communications Enabling Intelligent Mobility. IEEE Access 8: 208892-208897 (2020) - [j66]Xiang Cheng, Yiran Li, Cheng-Xiang Wang, Xuefeng Yin, David W. Matolak:
A 3-D Geometry-Based Stochastic Model for Unmanned Aerial Vehicle MIMO Ricean Fading Channels. IEEE Internet Things J. 7(9): 8674-8687 (2020) - [j65]Wahab Khawaja, Özgür Özdemir, Fatih Erden, Ismail Güvenç, David W. Matolak:
Ultra-Wideband Air-to-Ground Propagation Channel Characterization in an Open Area. IEEE Trans. Aerosp. Electron. Syst. 56(6): 4533-4555 (2020) - [j64]Michael Walter, Dmitriy Shutin, Martin Schmidhammer, David W. Matolak, Alenka G. Zajic:
Geometric Analysis of the Doppler Frequency for General Non-Stationary 3D Mobile-to-Mobile Channels Based on Prolate Spheroidal Coordinates. IEEE Trans. Veh. Technol. 69(10): 10419-10434 (2020) - [c60]Alphan Sahin, David W. Matolak:
Golay Layer: Limiting Peak-to-Average Power Ratio for OFDM-based Autoencoders. ICC 2020: 1-7 - [i5]Alphan Sahin, David W. Matolak:
Golay Layer: Limiting Peak-to-Average Power Ratio for OFDM-based Autoencoders. CoRR abs/2002.07701 (2020) - [i4]Alphan Sahin, Nozhan Hosseini, Hosseinali Jamal, David W. Matolak:
DFT-spread-OFDM Based Chirp Transmission. CoRR abs/2008.03766 (2020) - [i3]Nozhan Hosseini, David W. Matolak:
Noncoherent Multiuser Chirp Spread Spectrum: Performance with Doppler and Asynchronism. CoRR abs/2011.06575 (2020)
2010 – 2019
- 2019
- [j63]Wahab Khawaja, Ismail Güvenç, David W. Matolak, Uwe-Carsten Fiebig, Nicolas Schneckenburger:
A Survey of Air-to-Ground Propagation Channel Modeling for Unmanned Aerial Vehicles. IEEE Commun. Surv. Tutorials 21(3): 2361-2391 (2019) - [j62]Ke Guan, Danping He, Bo Ai, David W. Matolak, Qi Wang, Zhangdui Zhong, Thomas Kürner:
5-GHz Obstructed Vehicle-to-Vehicle Channel Characterization for Internet of Intelligent Vehicles. IEEE Internet Things J. 6(1): 100-110 (2019) - [j61]Hosseinali Jamal, David W. Matolak:
Dual-Polarization FBMC for Improved Performance in Wireless Communication Systems. IEEE Trans. Veh. Technol. 68(1): 349-358 (2019) - [j60]Petros S. Bithas, Athanasios G. Kanatas, David W. Matolak:
Exploiting Shadowing Stationarity for Antenna Selection in V2V Communications. IEEE Trans. Veh. Technol. 68(2): 1607-1615 (2019) - [j59]Cesar Briso-Rodríguez, Ke Guan, David W. Matolak, Marion Berbineau:
Guest Editorial Special Section on Smart Rail Mobility: Communications, Signaling, and Emerging Technologies. IEEE Trans. Veh. Technol. 68(3): 2021-2023 (2019) - [j58]Nicolas Schneckenburger, Thomas Jost, Michael Walter, Giovanni Del Galdo, David W. Matolak, Uwe-Carsten Fiebig:
Wideband Air-Ground Channel Model for a Regional Airport Environment. IEEE Trans. Veh. Technol. 68(7): 6243-6256 (2019) - [j57]Michael Walter, Dmitriy Shutin, David W. Matolak, Nicolas Schneckenburger, Thomas Wiedemann, Armin Dammann:
Analysis of Non-Stationary 3D Air-to-Air Channels Using the Theory of Algebraic Curves. IEEE Trans. Wirel. Commun. 18(8): 3767-3780 (2019) - [c59]David W. Matolak, Mohanad Mohsen, Jinming Chen:
Path Loss at 5 GHz and 31 GHz for Two Distinct Indoor Airport Settings. EUSIPCO 2019: 1-5 - [c58]Mahfuza Khatun, Changyu Guo, David Matolak, Hani Mehrpouyan:
Indoor and Outdoor Penetration Loss Measurements at 73 and 81 GHz. GLOBECOM 2019: 1-5 - [c57]Nozhan Hosseini, David W. Matolak:
Chirp Spread Spectrum Signaling for Future Air-Ground Communications. MILCOM 2019: 153-158 - [c56]Mahfuza Khatun, Changyu Guo, Letizia Moro, David Matolak, Hani Mehrpouyan:
Millimeter-Wave Path Loss at 73 GHz in Indoor and Outdoor Airport Environments. VTC Fall 2019: 1-5 - [c55]Jinwen Liu, David W. Matolak, Mohanad Mohsen, Jinming Chen:
Path Loss Modeling and Ray-Tracing Verification for 5/31/90 GHz Indoor Channels. VTC Fall 2019: 1-6 - 2018
- [j56]Wen Chen, Ruisi He, David W. Matolak, Chintha Tellambura, Zhengguo Sheng:
IEEE Access Special Section Editorial: High Mobility 5G LTE-V: Challenges and Solutions. IEEE Access 6: 40221-40225 (2018) - [j55]Ismail Güvenç, Farshad Koohifar, Simran Singh, Mihail L. Sichitiu, David Matolak:
Detection, Tracking, and Interdiction for Amateur Drones. IEEE Commun. Mag. 56(4): 75-81 (2018) - [j54]Deepa Das, David W. Matolak, Susmita Das:
Spectrum occupancy prediction based on functional link artificial neural network (FLANN) in ISM band. Neural Comput. Appl. 29(12): 1363-1376 (2018) - [j53]Qi Wang, David W. Matolak, Bo Ai:
Shadowing Characterization for 5-GHz Vehicle-to-Vehicle Channels. IEEE Trans. Veh. Technol. 67(3): 1855-1866 (2018) - [c54]Ke Guan, Bo Ai, Danping He, David W. Matolak, Qi Wang, Zhangdui Zhong, Thomas Kürner:
Obstructed Vehicle-to-Vehicle Channel Modeling for Intelligent Vehicular Communications. GlobalSIP 2018: 1194-1198 - [c53]Mahfuza Khatun, Hani Mehrpouyan, David Matolak:
60-GHz Millimeter-Wave Pathloss Measurements in Boise Airport. GlobalSIP 2018: 1276-1280 - [c52]Mojtaba Ahmadi Almasi, Hani Mehrpouyan, David Matolak, Cunhua Pan, Maged Elkashlan:
Reconfigurable Antenna Multiple Access for 5G mmWave Systems. ICC Workshops 2018: 1-6 - [c51]Roohollah Amiri, Hani Mehrpouyan, Lex Fridman, Ranjan K. Mallik, Arumugam Nallanathan, David Matolak:
A Machine Learning Approach for Power Allocation in HetNets Considering QoS. ICC 2018: 1-7 - [c50]César Calvo-Ramírez, Zhuangzhuang Cui, César Briso, Ke Guan, David W. Matolak:
UAV Air-Ground Channel Ray Tracing Simulation Validation. ICCC Workshops 2018: 122-125 - [c49]Michael Walter, Dmitriy Shutin, Armin Dammann, David W. Matolak:
Modeling of Highly Non-Stationary Low Altitude Aircraft-to-Aircraft Channels. MILCOM 2018: 1-5 - [c48]Hosseinali Jamal, David W. Matolak:
PAPR Analysis for Dual-Polarization FBMC. MILCOM 2018: 1-5 - [c47]David W. Matolak:
3D Air-X UAV Communications: Challenges and Channel Modeling. Nets4Cars/Nets4Trains/Nets4Aircraft 2018: 3-15 - [c46]Petros S. Bithas, Athanasios G. Kanatas, David W. Matolak:
Shadowing-Based Antenna Selection for V2V Communications. PIMRC 2018: 106-110 - [c45]Roohollah Amiri, Hani Mehrpouyan, David Matolak, Maged Elkashlan:
Joint Power Allocation in Interference-Limited Networks via Distributed Coordinated Learning. VTC Fall 2018: 1-5 - [c44]Shivesh Hiranandani, Sameer Mohadikar, Wahab Khawaja, Özgür Özdemir, Ismail Güvenç, David Matolak:
Effect of Passive Reflectors on the Coverage of IEEE 802.11ad mmWave Systems. VTC Fall 2018: 1-6 - [c43]Hosseinali Jamal, David W. Matolak:
Dual-Polarization OFDM-OQAM Wireless Communication System. VTC Fall 2018: 1-5 - [c42]David W. Matolak, Hosseinali Jamal:
Aviation Multicarrier Communication System Performance in Several 5 GHz Band Air-Ground Channels - Invited Paper. VTC Spring 2018: 1-5 - [c41]Jinwen Liu, David W. Matolak:
Modeling millimeter wave tropospheric attenuations for UAS and terrestrial aviation communications. WTS 2018: 1-9 - [c40]Mohanad Mohsen, David W. Matolak:
31 GHz path loss measurement and modeling for indoor/outdoor environments. WTS 2018: 1-8 - [i2]Roohollah Amiri, Hani Mehrpouyan, Lex Fridman, Ranjan K. Mallik, Arumugam Nallanathan, David Matolak:
A Machine Learning Approach for Power Allocation in HetNets Considering QoS. CoRR abs/1803.06760 (2018) - [i1]Mojtaba Ahmadi Almasi, Hani Mehrpouyan, David Matolak, Cunhua Pan, Maged Elkashlan:
Reconfigurable Antenna Multiple Access for 5G mmWave Systems. CoRR abs/1803.09918 (2018) - 2017
- [j52]Liu Liu, David W. Matolak, Cheng Tao, Yongzhi Li:
Analysis of an Upper Bound on the Effects of Large Scale Attenuation on Uplink Transmission Performance for Massive MIMO Systems. IEEE Access 5: 4285-4297 (2017) - [j51]Qi Wang, Bo Ai, David W. Matolak, Ruisi He, Ke Guan, Zhangdui Zhong, Dapeng Li:
Spatial Variation Analysis for Measured Indoor Massive MIMO Channels. IEEE Access 5: 20828-20840 (2017) - [j50]Ruoyu Sun, David W. Matolak:
Path loss and delay spread for the stairwell channel at 5 GHz. Int. J. Commun. Syst. 30(1) (2017) - [j49]David W. Matolak, Ruoyu Sun:
Air-Ground Channel Characterization for Unmanned Aircraft Systems - Part I: Methods, Measurements, and Models for Over-Water Settings. IEEE Trans. Veh. Technol. 66(1): 26-44 (2017) - [j48]Ruoyu Sun, David W. Matolak:
Air-Ground Channel Characterization for Unmanned Aircraft Systems Part II: Hilly and Mountainous Settings. IEEE Trans. Veh. Technol. 66(3): 1913-1925 (2017) - [j47]Ruoyu Sun, David W. Matolak, Pengyu Liu:
5-GHz V2V Channel Characteristics for Parking Garages. IEEE Trans. Veh. Technol. 66(5): 3538-3547 (2017) - [j46]Hosseinali Jamal, David W. Matolak:
FBMC and L-DACS Performance for Future Air-to-Ground Communication Systems. IEEE Trans. Veh. Technol. 66(6): 5043-5055 (2017) - [j45]David W. Matolak, Ruoyu Sun:
Air-Ground Channel Characterization for Unmanned Aircraft Systems - Part III: The Suburban and Near-Urban Environments. IEEE Trans. Veh. Technol. 66(8): 6607-6618 (2017) - [j44]Ruoyu Sun, David W. Matolak, William Rayess:
Air-Ground Channel Characterization for Unmanned Aircraft Systems - Part IV: Airframe Shadowing. IEEE Trans. Veh. Technol. 66(9): 7643-7652 (2017) - [j43]William Rayess, David W. Matolak, Savas Kaya, Avinash Karanth Kodi:
Antennas and Channel Characteristics for Wireless Networks on Chips. Wirel. Pers. Commun. 95(4): 5039-5056 (2017) - [c39]David W. Matolak, Hosseinali Jamal, Ruoyu Sun:
Spatial and frequency correlations in two-ray air-ground SIMO channels. ICC 2017: 1-6 - [c38]Hosseinali Jamal, David W. Matolak:
Enhanced airport surface multi-carrier communication systems: Filterbank advantages over AeroMACS OFDM. MILCOM 2017: 209-213 - 2016
- [j42]Liu Liu, David W. Matolak, Cheng Tao, Yongzhi Li, Bo Ai, Houjin Chen:
Channel capacity investigation of a linear massive MIMO system using spherical wave model in LOS scenarios. Sci. China Inf. Sci. 59(2): 1-15 (2016) - [j41]Ke Guan, Bo Ai, Alexander Fricke, Danping He, Zhangdui Zhong, David W. Matolak, Thomas Kürner:
Excess Propagation Loss Modeling of Semiclosed Obstacles for Intelligent Transportation System. IEEE Trans. Intell. Transp. Syst. 17(8): 2171-2181 (2016) - [j40]Pengyu Liu, Bo Ai, David W. Matolak, Ruoyu Sun, Yan Li:
5-GHz Vehicle-to-Vehicle Channel Characterization for Example Overpass Channels. IEEE Trans. Veh. Technol. 65(8): 5862-5873 (2016) - [c37]Hosseinali Jamal, David W. Matolak:
Channel estimation in an over-water air-ground channel using low complexity OFDM-OQAM modulations. CCNC 2016: 453-458 - [c36]Wahab Khawaja, Ismail Güvenç, David Matolak:
UWB Channel Sounding and Modeling for UAV Air-to-Ground Propagation Channels. GLOBECOM 2016: 1-7 - [c35]Md. Ashif I. Sikder, Avinash Kodi, William Rayess, Dominic DiTomaso, David W. Matolak, Savas Kaya:
Exploring Wireless Technology for Off-Chip Memory Access. Hot Interconnects 2016: 92-99 - [c34]Hosseinali Jamal, David W. Matolak:
Multicarrier Air to Ground MIMO Communication System Performance. VTC Fall 2016: 1-5 - [c33]Liu Liu, David W. Matolak, Cheng Tao, Yongzhi Li, Houjin Chen:
Sum-Rate Capacity Investigation of Multiuser Massive MIMO Uplink Systems in Semi-Correlated Channels. VTC Spring 2016: 1-5 - [c32]Liu Liu, David W. Matolak, Cheng Tao, Yongzhi Li, Houjin Chen:
The Benefits of Large-Scale Attenuation over the Antenna Array in Massive MIMO Systems. VTC Fall 2016: 1-5 - [c31]Ali A. Nasir, Hani Mehrpouyan, David Matolak, Salman Durrani:
Non-coherent FSK: An attractive modulation set for millimeter-wave communications. WCNC 2016: 1-7 - 2015
- [j39]David W. Matolak, Marion Berbineau, David G. Michelson, Chen Chen:
Future railway communications [Guest Editorial]. IEEE Commun. Mag. 53(10): 60-61 (2015) - [j38]Soumyasanta Laha, Savas Kaya, David W. Matolak, William Rayess, Dominic DiTomaso, Avinash Karanth Kodi:
A New Frontier in Ultralow Power Wireless Links: Network-on-Chip and Chip-to-Chip Interconnects. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 34(2): 186-198 (2015) - [j37]Dominic DiTomaso, Avinash Karanth Kodi, David W. Matolak, Savas Kaya, Soumyasanta Laha, William Rayess:
A-WiNoC: Adaptive Wireless Network-on-Chip Architecture for Chip Multiprocessors. IEEE Trans. Parallel Distributed Syst. 26(12): 3289-3302 (2015) - [j36]David W. Matolak, Ruoyu Sun:
Unmanned Aircraft Systems: Air-Ground Channel Characterization for Future Applications. IEEE Veh. Technol. Mag. 10(2): 79-85 (2015) - [c30]David W. Matolak:
Unmanned aerial vehicles: Communications challenges and future aerial networking. ICNC 2015: 567-572 - [c29]David W. Matolak, Ruoyu Sun:
Air-ground channel characterization for unmanned aircraft systems: The near-urban environment. MILCOM 2015: 1656-1660 - [c28]Avinash Karanth Kodi, Md. Ashif I. Sikder, Dominic DiTomaso, Savas Kaya, Soumyasanta Laha, David W. Matolak, William Rayess:
Kilo-core Wireless Network-on-Chips (NoCs) Architectures. NANOCOM 2015: 33:1-33:6 - [c27]Liu Liu, David W. Matolak, Cheng Tao, Yanping Lu, Houjin Chen:
Far Region Boundary Definition of Linear Massive MIMO Antenna Arrays. VTC Fall 2015: 1-6 - [c26]Liu Liu, Cheng Tao, David W. Matolak, Yanping Lu, Bo Ai, Houjin Chen:
Stationarity Investigation of a LOS Massive MIMO Channel in Stadium Scenarios. VTC Fall 2015: 1-5 - 2014
- [j35]Bo Ai, Xiang Cheng, Thomas Kürner, Zhangdui Zhong, Ke Guan, Ruisi He, Lei Xiong, David W. Matolak, David G. Michelson, Cesar Briso-Rodríguez:
Challenges Toward Wireless Communications for High-Speed Railway. IEEE Trans. Intell. Transp. Syst. 15(5): 2143-2158 (2014) - [j34]Pengyu Liu, David W. Matolak, Bo Ai, Ruoyu Sun:
Path Loss Modeling for Vehicle-to-Vehicle Communication on a Slope. IEEE Trans. Veh. Technol. 63(6): 2954-2958 (2014) - [j33]David W. Matolak, Kate A. Remley, Chris L. Holloway, Qian Zhang, Qiong Wu:
Large-Scale Site and Frequency Diversity in Urban Peer-to-Peer Channels for Six Public-Safety Frequency Bands. IEEE Trans. Wirel. Commun. 13(4): 2025-2033 (2014) - [j32]Petros Karadimas, David W. Matolak:
Generic stochastic modeling of vehicle-to-vehicle wireless channels. Veh. Commun. 1(4): 153-167 (2014) - [j31]Qian Zhang, David W. Matolak:
Ad Hoc Network Duplexing, Multiplexing, and Multiple Access: Canonical Results for Two Limiting Topologies. Wirel. Pers. Commun. 75(2): 965-985 (2014) - [c25]Ruoyu Sun, David W. Matolak:
Over-Harbor Channel Modeling with Directional Ground Station Antennas for the Air-Ground Channel. MILCOM 2014: 382-387 - [c24]Pengyu Liu, Bo Ai, David W. Matolak, Ruoyu Sun:
V2V Path Loss Modeling for Example 5 GHz Overpass Channels. VTC Spring 2014: 1-5 - [c23]David W. Matolak, Ruoyu Sun:
Air-Ground Channel Characterization for Unmanned Aircraft Systems: The Hilly Suburban Environment. VTC Fall 2014: 1-5 - [c22]Qian Zhang, David W. Matolak:
Quantifying performance of duplexing, multiplexing and multiple access in mesh, relay, and ad-hoc networks. WOCC 2014: 1-6 - 2013
- [j30]David W. Matolak, Savas Kaya, Avinash Karanth Kodi:
Channel modeling for wireless networks-on-chips. IEEE Commun. Mag. 51(6) (2013) - [j29]Ruoyu Sun, David W. Matolak:
Characterization of the 5-GHz Elevator Shaft Channel. IEEE Trans. Wirel. Commun. 12(10): 5138-5145 (2013) - [j28]David W. Matolak, Qian Zhang, Qiong Wu:
Path Loss in an Urban Peer-to-Peer Channel for Six Public-Safety Frequency Bands. IEEE Wirel. Commun. Lett. 2(3): 263-266 (2013) - [c21]David W. Matolak, Ruoyu Sun:
Channel characteristics for elevator shafts at 5 GHz. GLOBECOM 2013: 3931-3935 - [c20]Savas Kaya, Soumyasanta Laha, Avinash Kodi, Dominic DiTomaso, David Matolak, William Rayess:
On ultra-short wireless interconnects for NoCs and SoCs: Bridging the 'THz Gap'. MWSCAS 2013: 804-808 - [c19]David W. Matolak:
V2V Communication Channels: State of Knowledge, New Results, and What's Next. Nets4Cars/Nets4Trains 2013: 1-21 - [c18]Dominic DiTomaso, Avinash Karanth Kodi, David W. Matolak, Savas Kaya, Soumyasanta Laha, William Rayess:
Energy-efficient adaptive wireless NoCs architecture. NOCS 2013: 1-8 - [c17]Ruoyu Sun, David W. Matolak, Pengyu Liu:
Parking Garage Channel Characteristics at 5 GHz for V2V Applications. VTC Fall 2013: 1-5 - 2012
- [j27]David W. Matolak, Avinash Karanth Kodi, Savas Kaya, Dominic DiTomaso, Soumyasanta Laha, William Rayess:
Wireless networks-on-chips: architecture, wireless channel, and devices. IEEE Wirel. Commun. 19(5): 58-65 (2012) - [c16]Qian Zhang, David W. Matolak:
Ad hoc network metrics: Which is best? GLOBECOM 2012: 38-43 - [c15]Camillo Gentile, David W. Matolak, Kate A. Remley, Chris L. Holloway, Qiong Wu, Qian Zhang:
Modeling urban peer-to-peer channel characteristics for the 700 MHz and 4.9 GHz public safety bands. ICC 2012: 4557-4562 - [c14]Dominic DiTomaso, Soumyasanta Laha, Avinash Kodi, Savas Kaya, David Matolak:
Evaluation and performance analysis of energy efficient wireless NoC architecture. MWSCAS 2012: 798-801 - [c13]Dominic DiTomaso, Soumyasanta Laha, Savas Kaya, David W. Matolak, Avinash Kodi:
Energy efficient modulation for a wireless network-on-chip architecture. NEWCAS 2012: 489-492 - [c12]David W. Matolak, Arvind Chandrasekaran:
5 GHz Intra-Vehicle Channel Characterization. VTC Fall 2012: 1-5 - 2011
- [j26]David W. Matolak, Jeff Frolik:
Worse-than-Rayleigh fading: Experimental results and theoretical models. IEEE Commun. Mag. 49(4): 140-146 (2011) - [c11]Dominic DiTomaso, Avinash Karanth Kodi, Savas Kaya, David W. Matolak:
iWISE: Inter-router Wireless Scalable Express Channels for Network-on-Chips (NoCs) Architecture. Hot Interconnects 2011: 11-18 - [c10]Qian Zhang, David W. Matolak:
Multiple access in mesh and relay networks: Continuous single-carrier waveforms are superior to bursted multi-carrier waveforms. MILCOM 2011: 890-895 - [c9]David W. Matolak, Qiong Wu, Juan Jesús Sánchez Sánchez, David Morales-Jiménez, M. Carmen Aguayo-Torres:
Performance of LTE in Vehicle-to-Vehicle Channels. VTC Fall 2011: 1-4 - 2010
- [j25]Jingtao Zhang, David W. Matolak:
Transmitted power allocation/control for multi-band MC-CDMA. Phys. Commun. 3(3): 139-146 (2010) - [j24]Qiong Wu, David W. Matolak, Indranil Sen:
5-GHz-Band Vehicle-to-Vehicle Channels: Models for Multiple Values of Channel Bandwidth. IEEE Trans. Veh. Technol. 59(5): 2620-2625 (2010) - [j23]Wenhui Xiong, David W. Matolak:
Spectrally Shaped DS-CDMA with Dual Sideband Combining for Increased Diversity on Dispersive Fading Channels. Wirel. Pers. Commun. 54(4): 605-621 (2010)
2000 – 2009
- 2009
- [j22]Jingtao Zhang, David W. Matolak:
Multiple level orthogonal codes and their application in MC-CDMA systems. Comput. Commun. 32(3): 492-500 (2009) - [j21]David W. Matolak:
Probability density functions for SNIR in DS-CDMA. IEEE Trans. Commun. 57(6): 1628-1633 (2009) - 2008
- [j20]David W. Matolak:
Channel Modeling for Vehicle-To-Vehicle Communications. IEEE Commun. Mag. 46(5): 76-83 (2008) - [j19]David W. Matolak, Indranil Sen, Wenhui Xiong:
Generation of multivariate Weibull random variates. IET Commun. 2(4): 523-527 (2008) - [j18]Indranil Sen, David W. Matolak:
Vehicle-Vehicle Channel Models for the 5-GHz Band. IEEE Trans. Intell. Transp. Syst. 9(2): 235-245 (2008) - [j17]David W. Matolak, Indranil Sen, Wenhui Xiong:
The 5-GHz Airport Surface Area Channel - Part I: Measurement and Modeling Results for Large Airports. IEEE Trans. Veh. Technol. 57(4): 2014-2026 (2008) - [j16]Indranil Sen, David W. Matolak:
The 5-GHz Airport Surface Area Channel - Part II: Measurement and Modeling Results for Small Airports. IEEE Trans. Veh. Technol. 57(4): 2027-2035 (2008) - [j15]Wenhui Xiong, David W. Matolak:
Spectrally shaped generalized MC-DS-CDMA with dual band combining for increased diversity. IEEE Trans. Wirel. Commun. 7(5-1): 1676-1686 (2008) - [c8]Jingtao Zhang, David W. Matolak:
FG-MC-CDMA System Performance in Multi-band Channels. CNSR 2008: 132-138 - 2007
- [j14]David W. Matolak, Beibei Wang:
Efficient statistical parallel interference cancellation for DS-CDMA in Rayleigh fading channels. IEEE Trans. Wirel. Commun. 6(2): 566-574 (2007) - [j13]Indranil Sen, David W. Matolak:
V2V channels and performance of multiuser spread spectrum modulation. IEEE Veh. Technol. Mag. 2(4): 19-25 (2007) - [j12]Indranil Sen, David W. Matolak:
Bandwidth efficient MT-DS-SS via reduced subcarrier frequency spacing. Wirel. Pers. Commun. 43(4): 1419-1433 (2007) - [c7]Beibei Wang, David W. Matolak:
Improved DS-CDMA Multi-stage PIC in Fading Channels using a Generalized Soft Limiter. ICC 2007: 4462-4467 - [c6]Beibei Wang, David W. Matolak:
Statistical PIC in Multirate DS-CDMA Systems Over Dispersive Fading Channels. VTC Fall 2007: 1032-1036 - [c5]Beibei Wang, Indranil Sen, David W. Matolak:
Performance Evaluation of 802.16e in Vehicle to Vehicle Channels. VTC Fall 2007: 1406-1410 - [c4]Indranil Sen, David W. Matolak:
V2V Channels and Performance of Multi-User Spread Spectrum Modulation. VTC Fall 2007: 2139-2143 - 2006
- [j11]David W. Matolak:
Simplified group interference cancelling for asynchronous DS-CDMA. Int. J. Commun. Syst. 19(10): 1117-1136 (2006) - [j10]David W. Matolak, Joshua T. Neville:
Performance and Capacity of Direct-Sequence Spread Spectrum Overlay in the Microwave Landing System Band. J. Aerosp. Comput. Inf. Commun. 3(1): 28-43 (2006) - [j9]David W. Matolak:
TDMA and CDMA Capacities in Air-Ground Communications. J. Aerosp. Comput. Inf. Commun. 3(7): 340-353 (2006) - [j8]David W. Matolak, Wenhui Xiong:
Spectrally shaped generalized multitone direct sequence spread spectrum. IEEE Trans. Veh. Technol. 55(4): 1224-1238 (2006) - [c3]David W. Matolak, Indranil Sen, Wenhui Xiong:
Channel Modeling for V2V Communications. MobiQuitous 2006: 1-7 - 2005
- [j7]Hongxiang Li, David W. Matolak:
Phase noise and fading effects on system performance in MT-DS-SS. IEEE Trans. Veh. Technol. 54(5): 1759-1767 (2005) - [j6]David W. Matolak:
Asynchronous DS-SS CDMA random spreading code correlation statistics in the presence of timing error. IEEE Trans. Veh. Technol. 54(5): 1908-1911 (2005) - [c2]Wenhui Xiong, David W. Matolak:
Performance of Hamming codes in systems employing different code symbol energies. WCNC 2005: 1055-1058 - 2004
- [j5]David W. Matolak:
A new multi-state fading model for mobile satellite channels based upon AFD and LCR data. Int. J. Satell. Commun. Netw. 22(2): 181-192 (2004) - [j4]David W. Matolak, Joshua T. Neville:
Spectral Overlay of Direct-Sequence Spread Spectrum in the Instrument Landing System Glideslope Band. J. Aerosp. Comput. Inf. Commun. 1(10): 407-416 (2004) - 2001
- [c1]David M. Chelberg, Lonnie R. Welch, Cynthia R. Marling, Carl Bruggeman, Douglas Lawrence, David W. Matolak, Robert L. Williams II, Jae Y. Lew, Arvind Lakshmikumar, Matthew Gillen, Qiang Zhou, Barbara Pfarr:
A Dynamic, Real-Time Testbed for Resource Management Technology. IPDPS 2001: 88 - 2000
- [j3]David W. Matolak:
3-D outside cell interference factor for an air-ground CDMA "cellular" system. IEEE Trans. Veh. Technol. 49(3): 706-710 (2000)
1990 – 1999
- 1996
- [j2]David W. Matolak, Stephen G. Wilson:
Variable-complexity trellis decoding of binary convolutional codes. IEEE Trans. Commun. 44(2): 121-126 (1996) - [j1]David W. Matolak, Stephen G. Wilson:
Detection for a statistically known, time-varying dispersive channel. IEEE Trans. Commun. 44(12): 1673-1683 (1996)
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 2024-10-25 21:13 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:
