Harris.com W. N. Furman, J.W. Nieto, W.M. Batts HFIA Meeting 09/24/2015 Interpretation of HF channel parameters based on waterfall spectrograms.

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Presentation transcript:

harris.com W. N. Furman, J.W. Nieto, W.M. Batts HFIA Meeting 09/24/2015 Interpretation of HF channel parameters based on waterfall spectrograms

| 2 | Overview Example waterfall spectrogram A surprise(?) Experimental block diagram Key building blocks Possible solution(?) Moving forward Another example waterfall spectrogram

| 3 | Example waterfall spectrogram April 7,2015, 16km link, H Doublet & Inverted V antenna, ~100 Watts, MIL-STD C-D, Harris WMT/STANAG5066 Click to view video

| 4 | A Surprise (?) 16 km link Expected nice ground wave link Fading and multipath, as evidenced by nulls in the spectrogram confirmed that we had sky wave propagation components Important fact –Multipath introduces frequency selective nulls that are spaced 1/T apart, where T is the multipath spread in seconds –Frequency offset on a path will slide the null across the signal spectrum Question –Could we use the HF Channel Simulator to introduce channel degradations to replicate the captured waterfall spectrogram? –Could this approach be used as a tool to understand propagation related channel effects?

| 5 | Experimental Block Diagram HF Channel simulator parameters are adjusted so that the waterfall spectrogram is similar to those collected on-air HF Channel Simulator I/Q WAV 96ksps Parameters I/Q WAV 96ksps 24 KHz WB HF Sample rate Converter Perseus File Header I/Q WAV 2Msps

| 6 | Key Building Blocks 1 path, (0dB, 0ms, 0Hz, 0 Hz) 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 2ms, 0Hz, 0 Hz) 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 0.2ms, 0Hz, 0 Hz) Path Definition: Gain(dB), delay(ms), Doppler Spread(Hz), Frequency Offset(Hz) 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 0.1ms, 0Hz, 0 Hz)

| 7 | Key Building Blocks 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 0.2ms, 0Hz, 1 Hz) 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 0.2ms, 0Hz, -1 Hz) 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 0.2ms, 0Hz, 0.1 Hz) 2 path, (0dB, 0ms, 0Hz, 0 Hz) (0dB, 0.2ms, 0Hz, 0.2 Hz)

| 8 | A Possible Solution 3 path, (-20dB, 0ms, 0Hz, 0 Hz) (0dB, 2ms, 0.2Hz, -0.2 Hz) (0dB, 2.1ms, 0.3Hz, 0 Hz) Click to view video

| 9 | A Possible Solution #2 3 path, (-5dB, 0ms, 0Hz, 0 Hz) (0dB, 2ms, 0.2Hz, -0.2 Hz) (0dB, 2.1ms, 0.3Hz, 0.4 Hz) Click to view video

| 10 | Moving Forward Collect more waterfall spectrograms on various links –NVIS ( < 200 km) –Long haul ( km) links Simultaneously collect received waveform samples Process received samples by Wideband HF data modem Contrast and compare modem estimated channel parameters with graphically derived channel parameters Possibly enhance channel simulator to vary path delays as well as frequency offset, Doppler spread and Gain. Hope to report on results at Nordic HF16

| 11 | Another Example A video example from recent Stockbridge ( 160 km NVIS) run Click to view video