Effects of magnetic storms on GPS signals

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Transcription:

Effects of magnetic storms on GPS signals Andreja Sušnik Supervisor: doc.dr. Biagio Forte

Outline 1. Background - GPS system - Ionosphere 2. Ionospheric Scintillations 3. Experimental data 4. Conclusions

The GPS system? stands for Global Positioning System, is a U.S. space-based radio-navigation system that provides reliable positioning, navigation, and timing services to civil users on a continuous worldwide basis. The GPS system consist of three segments: - Space segment - Control segment - User segment

The GPS system Space segment - 24 to 36 satellites - in six orbital planes - at altitude 20,183 km

The GPS system Control segment

The GPS system User segment Applications: - navigation - geodesy - timing - surveying - surveillance - aviation - agriculture - cadastre

The GPS system - each GPS satellite transmits continuously using two radio frequencies in the L-band: L1 : 1.575 GHz L2 : 1.227 GHz Signal structure: - Carrier - Ranging code (pseudorandom codes, PRN) - Navigation data

The GPS system Signal Structure: Carrier Ranging code (pseudo-random codes, PRN) Navigation data

How does it work? http://www.little-yeti.com/gpsmanual/chapter01.htm

Error Sources Troposphere 1 orbit error = ± 2.5 meters 2 clock error = ± 2 meters 3 Ionospheric Delay = ± 5 meters 4 Tropospheric Delay = ± 0.5 meters 5 Multipath = ± 1 meters 6 Receiver noise = ± 1 meters http://www.soi.wide.ad.jp/

Ionospheric Delay - Group Delay - Phase Advance - Doppler Shift - Faraday Rotation - Ray-path bending - Random fluctuations, in both intensity and phase Total electron content = TEC Ionospheric scintillations TEC units 1 TECU = 10 16 electrons/m 2

Ionosphere - it is the upper part of the Earth s atmosphere that is ionized by solar radiation - it extends from about 75 to 1000 km and completely encircles the Earth Vertical structure of the Earth atmosphere Public domain image from WikiMedia Commons

Ionosphere The ionosphere is composed of three main layers: the D, E, and F regions: - F-region: 150-1000km contains a range of ions from NO + and O + at the bottom to H + and He + ions at the top. Electron density reaches an absolute maximum in this region, - E-region: 95-150km, contains mostly O 2 + and NO 2 + ions, with metallic long lived ions to a minor extent, - D-region: 75-95km up, relatively weak ionization due to its position at the bottom. Ionospheric layers and the corresponding electron densities

1. Background - GPS system - Ionosphere 1. Ionospheric Scintillations 2. Experimental data 3. Conclusions

Ionospheric Scintillations - GPS signal traversing Earth s atmosphere suffers distortion of phase and amplitude. - When it traverses small-scale ionospheric plasma-density irregularities, fading, phase fluctuations, and angle of arrival variations are experienced at the receivers IONOSPHERIC SCINTILLATION - varies widely with transmission frequency, magnetic and solar activity, season, and latitude

Ionospheric Scintillations (1) high latitude region the equatorial region middle latitudes middle latitudes high latitude region Global depth of scintillation fading (proportional to density of crosshatching), during low and moderate solar activity (Aarons and Basu, 85)

Ionospheric Scintillations (2) Pattern of ionospheric scintillation during solar maximum and solar minimum (Basu et al., 1988).

Ionospheric Scintillations (2) - scintillation of the GPS signals is a consequence of the existence of spatial electron-density fluctuations within the ionosphere z = 0 (0,0,z) L z L = irregularity slab receiver

Ionospheric Scintillations (3) - as the wave propagates through the irregularity slab, only the phase is affected by the random fluctuations in refractive index = is the free-space wavenumber, in the layer with irregularities. = is the variation of the optical path length within the layer with irregularities.

Ionospheric Scintillations (4) - as the wave propagates toward the receiver, further phase mixing occurs, changing the modulation of the wave L z (0,0,z) receiver

Ionospheric Scintillations (5) Assumption: - the temporal variations of the irregularities are much slower than the wave period - the characteristic size of irregularities is much greater than the wavelength PHASE SCREEN in which the irregular layer is replaced by a screen, changing only the wave s phase.

Ionospheric Scintillations (6) Scintillation activity - typically is measured by means of several indices: S 4 index the phase scintillation index = indicates ensemble averages = received intensity

Ionospheric Scintillations (7) SI index I 0 t

1. Background - GPS system - Ionosphere 2. Ionospheric Scintillations 3. Experimental data 4. Conclusions

Experimental data (1) - GPS scintillation monitor at the Dirigibile Italia Station (Ny Alesund, Svalbard) - the monitor is dual frequency GPS receiver able to record 50 Hz raw data (intensity and phase) - three magnetic storm events are considered, including quiet days prior the storm, main storm phases and recovery phases: from 6.12.2004 to 8.12.2004 from 23.1.2004 to 30.1.2004 from 8.1.2005 to 9.1.2005

Kp index for the day 2004-01-25

Kp index for the day 2004-12-7

Experimental data (2) - raw signal intensity and phase are detrended with a 6 th order Butterworth high-pass filter, in order to remove undesired effects from the signals dynamics. - three different values of the filter low frequency cutoff have been used: 0.1 Hz blue 0.3 Hz green 0.5 Hz red

Results 0400-0500 UT on the day 2004-01-25, PRN 28

Results 0400-0500 UT on the day 2004-01-25, PRN 28

Results 0400-0500 UT on the day 2004-01-25,PRN 28

Results 0400-0500 UT on the day 2004-01-25, PRN 28

Results 1800-1900 UT on the day 2004-12-7,PRN 3

Results 1800-1900 UT on the day 2004-12-7,PRN 3

Results 1800-1900 UT on the day 2004-12-7,PRN 3

Results 1800-1900 UT on the day 2004-12-7,PRN 3

Conclusions - an erroneous data detrending can be responsible for misleading data interpretation - the new indices so far suggested show a better description of the events analyzed in terms of the measured scintillation activity - more analyses will be done in the future on datasets from the African and Brazilian low latitudes sectors - more experimental data at middle latitudes during solar maximum will be recorded at the UNG atmospheric observatory (Otlica) - more experimental information at middle latitudes will be carried out by a TEC polarimeter to be implemented at the Otlica observatory later this year.

Thank you!

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