An Efficient Propagation Simulator for High Frequency Signals And Results from HF radar experiment
34
An Efficient Propagation Simulator for High Frequency Signals And Results from HF radar experiment Kin Shing Bobby Yau Supervisors: Dr. Chris Coleman & Dr. Bruce Davis School of Electrical and Electronic Engineering The University of Adelaide, Australia
description
An Efficient Propagation Simulator for High Frequency Signals And Results from HF radar experiment. Kin Shing Bobby Yau Supervisors: Dr. Chris Coleman & Dr. Bruce Davis School of Electrical and Electronic Engineering The University of Adelaide, Australia. Overview. - PowerPoint PPT Presentation
Transcript of An Efficient Propagation Simulator for High Frequency Signals And Results from HF radar experiment
An Efficient Propagation Simulator for High Frequency
Signals
And Results from HF radar experiment
Kin Shing Bobby Yau
Supervisors: Dr. Chris Coleman & Dr. Bruce Davis
School of Electrical and Electronic Engineering
The University of Adelaide, Australia
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 2
Overview
HF Ionospheric Propagation Simulator Simulation results Comparisons with Experimental Results Discussions Conclusions
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 3
Introduction
HF radio system is still prevalent Military Over-the-Horizon RADAR HF communications Commercial broadcasting
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 4
Ionospheric Propagation Simulator
A need for wideband HF propagation simulator
Focussing on the fading effects of HF signals
Employ theoretical model of fading Efficient algorithm based on analytical expressions
Two components of fading model: Polarization Fading Model Amplitude Fading Model
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 5
Lower path – Extraordinary waveRight-hand circular
polarisation
Upper path – Ordinary wave
Left-hand circular polarisation
Polarization Fading Model
Faraday rotation due to O and X wave interference
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 6
Polarization Fading Model
Perturbation techniques to ascertain the change in phase path due to irregularities
dgdsPdunperturbedunperturbe
Use of frequency offset method to take into account of the magnetic field
Hxo fff cos2
1,
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 7
Amplitude Fading Model Focussing and defocussing of radio
waves due to movement of large scale ionospheric structure
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 8
Amplitude Fading Model
Parabolic approximation to Maxwell’s equation (Wagen and Yeh):
0),(2 22
Utgkt
U
g
Ukj oo
U is the complex amplitude, is the refractive index with irregularities
g and t are the local longitudinal and transverse coordinates
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 9
Amplitude Fading Model
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 10
Simulator Implementation Numerical ray
tracing is used for the path quantities
Accurate ray homing for finding all possible paths (Strangeways, 2000)
Fading is calculated by the fading models
Ionospheric condition information
Simulation parameters
Ray Tracing Engine(RTE)
Polarisation Fading Model(PFM)
Amplitude Fading Model(AFM)
Ionospheric Propagation Simulator(IPS)
Data Display Module
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 11
Simulation Results
Alice Springs to Darwin
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 12
Simulation Results 10.6MHz - = 0.05, L = 350km, v = 200m/s
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 13
Simulation Results 10.6MHz - = 0.05, L = 350km, v = 200m/s
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 14
Simulation Results 10.6MHz - = 0.05, L = 350km, v = 200m/s
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 15
Simulation Results 10.6MHz - = 0.20, L = 350km, v = 200m/s
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 16
Simulation Results 10.6MHz - = 0.20, L = 350km, v = 200m/s
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 17
Simulation Results 10.6MHz - = 0.20, L = 350km, v = 200m/s
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 18
Comparison – Experimental Results
Signals from Jindalee Radar transmitter in Alice Springs
Dual-polarization receiver in Darwin
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 19
Experimental Results
Finding the signal component along each sweep
FMCW Radar signal
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 20
Experimental Results
6:30PM local time – Spectrograms
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 21
Experimental Results
6:30PM local time – Time fading
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 22
Experimental Results
6:30PM local time – Frequency fading
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 23
Experimental Results
7:30PM local time – Spectrograms
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 24
Experimental Results
7:30PM local time – Time fading
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 25
Experimental Results
7:30PM local time – Frequency fading
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 26
Fading Separation
Separate amplitude and polarisation fading Two orthogonal antennas:
)),(cos(),( tftfAVH )),(sin(),( tftfAkVV A - amplitude component
- phase component Therefore:
H
V
Vk
Vtan )tan1( 222 HVA
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 27
Fading Separation
7:30PM local time – Time fading revisited
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 28
Fading Separation
7:30PM local time – Time fading separation
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 29
Fading Separation
6:30PM local time – Time fading revisited
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 30
Fading Separation
6:30PM local time – Time fading separation
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 31
Fading Separation
Fading separation works well for single-mode case
For multi-mode propagation: Exploit FMCW radar signals Separating the modes using Range-gating
techniques Applying fade separation to each of the modes
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 32
Discussion
Further analyzing with experimental data Comparisons with ionosonde data
Discover the structure of the ionosphere during the period of rapid fading
Simulating propagation under realistic irregularity strctures
Possible applications: Real-Time channel evaluation Test-bed for fading mitigation techniques
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 33
Conclusion
Efficient Ionospheric Propagation Simulator has been developed
Experiment to observe fading of HF signals was done successfully
Comparisons between experiment and simulation are promising, especially for single-path polarization fading
More work to be done on the experimental data
An Efficient Ionospheric Propagation Simulator for High Frequency Signals - Page 34
Acknowledgements
Defence Science and Technology Organisation (DSTO)
Dr. Manuel Cevira Dr. Chris Coleman
