When the Solar wind blows GNSS positioning off course

Septentrio_GNSS_accurate_reliable_receiver_bluetooth_Wi-Fi_WiFi_PolaRx_AsteRx_Altus_receiver_interference_insights_scintilation_Ghana_sun_power_Earth_atmosphere_ionosphere_satellite_signals_equator_inshite

For a large dredging company working in Ghana, the heat wasn’t the only problem the sun was causing on-site. The availability and accuracy of their industrial GNSS receivers was Image_Insights_Scintillation_Septentrio_PolaRx5S_PolaRx5_UNAVCO_Accuracy_Reliability_running into problems resulting in work repeatedly grinding to a halt. Analysis of data recorded on-site by Septentrio’s engineers was able to place the blame firmly at the door of the sun. The year was 2012 and the sun was reaching the peak of its 11-year activity cycle and, with this came increasingly frequent and intense disturbances to the upper layers of the Earth’s atmosphere. It was these disturbances that were ultimately found to be responsible for the behaviour of the GNSS receiver.         

 

The ionosphere, scintillation and satellite signals

Image_Insights_Septentrio_Sarah_Scintillation_Accuracy_Reliability_PolaRx5_Jean-Marie Sleewaegen Signals from GNSS satellites travel the majority of their 20,000 km journey to Earth largely unhindered. However, refraction and diffraction of GNSS signals in the Earth’s atmosphere, particularly the outermost ionosphere, can result in delays and distortions to the signals. As the name suggests, the ionosphere contains particles that have become charged, or ionised, as a result of interactions with high-energy particles from the sun. When these ionised particles are smoothly or homogeneously distributed, GNSS receivers can take into account the effect they have on satellite signals using models. Problems arise when there are irregularities in the ionosphere. These irregularities are localised fluctuations in the electron density of the ionosphere and can distort the phase and amplitude of GNSS signals producing fluctuations known as scintillations. Ionospheric scintillations are typically characterised by two indices:

  • S4: the amplitude scintillation index and; 
  • σφ: the phase scintillation index

 

Where?

Scintillation events are most frequent and intense in the regions around the magnetic equator Image_Septentrio_Insights_Where_in_the_World_Scintillation_Sarah_Accuracy_Reliablity_GNSS_Receiver_PolaRx5_UNAVCOand also, but to a lesser extent, at the poles. Similar to other natural phenomena, their appearance is unpredictable with scintillation events having been reported in the mid-latitude regions of Western Europe and the United States.

When?

The activity of the sun, as Insight_Scintillation_Septentrio_Accurate_Reliable_GNSS_Positioningmeasured by the number of sunspots, follows a well-documented 11-year cycle. The peaks in solar activity are characterised by frequent solar flares releasing powerful bursts of high-energy protons and X-rays. These particles then interact with the Earth’s atmosphere contributing to an increase in scintillation events in the years close to solar activity peaks.Scintillation events also show variation over the course of the day with sunset triggering a sharp increase in ionospheric activity that can last for several hours. 

Image_Insights_Scintillation_Sarah_Septentrio_Accuracy_Reliability_PolaRx5S_PolaRx5_throughout_dayScintillation events also show variation over the course of the day with sunset triggering a sharp increase in ionospheric activity that can last for several hours. 

What does scintillation mean for GNSS positioning?

GPS or more generally, GNSS (Global Navigation Satellite System) receivers use the signals from satellites orbiting the earth to calculate their locations. An increase in solar activity can produce so-called scintillation events in the ionosphere which can degrade the quality of satellite signals. In standard GNSS receivers, mild scintillation can degrade position accuracy by up to several meters. More severe scintillation can cause cycle slips or, in the most extreme cases, total loss of signal lock. During these times, even normal radio communication can be severely disturbed by scintillation. So, whether you are doing precision agriculture in Brazil, oil exploration in Alaska or running a large construction project in Singapore, you had better make sure your precsion GNSS system comes with ionospheric robustness built in.

 

Honing our IONO+ algorithms in Brazil

As a direct result of Septentrio_Insights_Scintillaton_involvement in various projects in Brazil, a country typically plagued by scintillation, Septentrio has developed IONO+ technology. Equipped with IONO+, Septentrio receivers can continue to track signals in conditions that would frustrate standard receivers. It also enables Septentrio receivers to recognise scintillation events and limit any adverse effect they might have on position accuracy. The plot opposite shows the height calculated by a static receiver during a scintillation event: the IONO+ algorithms correctly identify and remove signals affected by scintillation from the position calculation