According to our database1, Jordan Melzer authored at least 14 papers between 2014 and 2019.
Legend:Book In proceedings Article PhD thesis Other
Simplified User Grouping Algorithm for Massive MIMO on Sparse Beam-Space Channels.
IEICE Transactions, 2019
Rotating cluster mechanism for coordinated heterogeneous MIMO cellular networks.
EURASIP J. Wireless Comm. and Networking, 2018
Investigation of Wideband Substrate-Integrated Vertically-Polarized Electric Dipole Antenna and Arrays for mm-Wave 5G Mobile Devices.
IEEE Access, 2018
Modeling of Cellular Networks Using Stationary and Nonstationary Point Processes.
IEEE Access, 2018
Robust precoder design for massive MIMO with peak total power constrained single-RF-chain transmitters.
IET Communications, 2017
Hybrid beamforming and DFT-based channel estimation for millimeter wave MIMO systems.
Proceedings of the 28th IEEE Annual International Symposium on Personal, 2017
Massive MIMO With Nonlinear Precoding: Large-System Analysis.
IEEE Trans. Vehicular Technology, 2016
Bandwidth aggregation using MPTCP and WMN gateways.
Proceedings of the 2016 IEEE Canadian Conference on Electrical and Computer Engineering, 2016
A path selection algorithm for sparse massive MIMO channels.
Proceedings of the 50th Asilomar Conference on Signals, Systems and Computers, 2016
A Novel Low-Complexity Joint User-Relay Selection and Association for Multi-User Multi-Relay MIMO Uplink.
IEEE Wireless Commun. Letters, 2015
Autoconfiguration for faster WiFi community networks.
Proceedings of the IFIP/IEEE International Symposium on Integrated Network Management, 2015
Aggregating Internet access in a mesh-backhauled network through MPTCP proxying.
Proceedings of the International Conference on Computing, Networking and Communications, 2014
Rotating clustering with simulated annealing user scheduling for coordinated heterogeneous MIMO cellular networks.
Proceedings of the IEEE International Conference on Communications, 2014
Effect of cluster rotation speed in coordinated heterogeneous MIMO cellular networks with proportionally fair user scheduling.
Proceedings of the 48th Asilomar Conference on Signals, Systems and Computers, 2014