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|Type: ||Journal article|
|Title: ||HiCIRF: a high-fidelity HF channel simulation|
|Author: ||Nickisch, L. J.|
St. John, Gavin
Fridman, Sergey V.
Hausman, Mark A.
Coleman, Christopher John
|Citation: ||Radio Science, 2012; 47(4):RSOL11|
|Publisher: ||American Geophysical Union|
|Issue Date: ||2012|
|School/Discipline: ||School of Electrical and Electronic Engineering|
|L.J. Nickisch, Gavin St. John, Sergey V. Fridman, Mark A. Hausman and C.J. Coleman|
|Abstract: ||A high-fidelity HF channel simulation has been developed that is suitable for Over-the-Horizon Radar (OTHR) and HF communication system design studies and test planning. The simulation capability is called HiCIRF, for High-frequency Channel Impulse Response Function. HiCIRF provides simulated HF signals corresponding to transmissions from individual transmitter array elements to individual receiver array elements for propagation through the naturally disturbed or undisturbed ionospheric channel. Both one-way link geometries and two-way radar geometries can be simulated. HiCIRF incorporates numerical ray tracing and stochastic signal structure computations to realistically simulate signal scatter by small-scale ionization structure. Stochastic signal generation is employed to generate signal realizations that can be used for OTHR array design and advanced signal processing studies.|
|Rights: ||Copyright 2012 by the American Geophysical Union|
|Appears in Collections:||Electrical and Electronic Engineering publications|
|View citing articles in: ||Web of Science|
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