Authors :
Aisha Chauhan; Sarvjit Singh; Preeti Gupta
Volume/Issue :
Volume 7 - 2022, Issue 12 - December
Google Scholar :
https://bit.ly/3IIfn9N
Scribd :
https://bit.ly/3HaLfpW
DOI :
https://doi.org/10.5281/zenodo.7542564
Abstract :
This paper represents experimentally
determined large-scale and small-scale channel model
parameters for 28 GHz and 73 GHz that describe the
typical temporal and angular characteristics of
multipath components for 5G communication. New York
University researchers created a statistical spatial
channel model for broadband millimeter-wave
(mmWave) wireless communication systems, which
served as the foundation for NYUSIM (NYU). The
simulator works with a variety of carrier frequencies
(500 MHz to 100 GHz). We display the 32x32 graphs
between the transceivers using the NYUSIM.
Performance demonstrates that the directed PDP (Path
Delay Profile) has the best performance and that the
PLE (Path Loss Exponential) is greater than the Line Of
Sight (LOS).
Keywords :
mmWave, MIMO (Multiple Input Multiple Output), 5G, NYUSIM
This paper represents experimentally
determined large-scale and small-scale channel model
parameters for 28 GHz and 73 GHz that describe the
typical temporal and angular characteristics of
multipath components for 5G communication. New York
University researchers created a statistical spatial
channel model for broadband millimeter-wave
(mmWave) wireless communication systems, which
served as the foundation for NYUSIM (NYU). The
simulator works with a variety of carrier frequencies
(500 MHz to 100 GHz). We display the 32x32 graphs
between the transceivers using the NYUSIM.
Performance demonstrates that the directed PDP (Path
Delay Profile) has the best performance and that the
PLE (Path Loss Exponential) is greater than the Line Of
Sight (LOS).
Keywords :
mmWave, MIMO (Multiple Input Multiple Output), 5G, NYUSIM