Interferometric phase (Δφ) is impacted by four contributions:

• topographic distortions arising from slightly different viewing angles of the two satellite passes (t)
• atmospheric effects (α) arising from the wavelength distortion that occurs when signals enter and leave a moisture-bearing layer
• any range (distance between the sensor and the target) displacement of the radar target (∆R)
• noise

These factors, expressed more precisely, are given in the equation below:

It is clear that the difficulties related to the estimation of surface deformation signals from a single SAR interferogram are essentially due to the presence of decorrelation effects (contributing to the noise level), the impact of local topography on phase values and the presence of atmospheric phase components superimposed on the signal of interest. In Figure 2, most of the fringes visible in the interferogram are due to co-seismic deformation induced by the earthquake: in fact, the impact of the local topography has been removed and atmospheric disturbances are not evident in this image.
 

Interferometric fringes can only be observed where image coherence prevails.  When an area on the ground appears to have the same surface characterization in all images under analysis, the images are said to be coherent. If the land surface is disturbed between two acquisitions (e.g. an agricultural field has been ploughed, tree leaves have moved positions, etc.), those sub-areas will decorrelate in an InSAR analysis, resulting in noise and no information being obtainable.  Coherence and correlation have the same meaning in this context.  The term ‘noise’ is frequently used in this context and it is another word for non-coherence, or decorrelation. The fringes visible in Figure 2 reveal areas with high coherence while the speckled areas represent very low coherence and noise.

The coherence of an interferogram is affected by several factors, including:

• Topographic slope angle and orientation (steep slopes lead to low coherence)
• Terrain properties
• The time between image acquisitions (the longer the time interval the lower the coherence)
• The distance between the satellite tracks during the first and second acquisitions, also referred to as the baseline (larger baselines lead to lower coherence)

Typical sources of decorrelation are:

• Vegetation: leaves grow and die and they also move.  From one scene to the next, these changes are sufficient to change the appearance of the surface characterization.  This is a particular problem for X-band and C-band sensors. L-band sensors can overcome this limitation in many situations, because their significantly longer wavelength is able to ‘see’ through foliage and reflect off objects beneath the vegetation and back through the foliage.
• Construction: at a construction site, the appearance of the land surface is changing constantly.  This can a problem that is common to X-band, C-band, and L-band sensors.
• Erosion: whether prompted by rain, snowmelt or wind, surface erosion will also change the surface characterization of land and, thereby, can decorrelate those areas where erosion is prevalent.
• Rapid movement: landslides and earthquakes precipitate rapid motion of an area of land.  Quite often, the rapid motion causes destruction and, with it, a total change in the land surface appearance. With earthquakes, it is sometimes possible for rapid motion to occur without changes to surface characterization and, in those situations, interferometry can be successful.  If the total movement occurring between successive image acquisitions exceeds one-half of the signal wavelength, decorrelation is likely to occur.

Coherence is measured by an index ranging from 0 to 1.  When an area is completely coherent, it has a coherence value of 1.  Correspondingly, if an area completely decorrelates, its coherence index is 0.  In general, interferometry is successful and accurate deformation is measurable when the coherence index lies between 0.5 and 1.0.  Interferometry can still produce meaningful results with coherence levels below 0.5 but as the index gets lower, so the results will display increasing levels of noise and may show erratic deformation patterns from scene to scene, although movement trends are visible and generally reliable.

Wherever fringes occur, it is possible to calculate deformation by calculating the number of fringes and multiplying them by half of the wavelength.  In the case of L’Aquila, C-band SAR was used and therefore each fringe should be multiplied by 28mm (one-half of the wavelength) to calculate the total apparent displacement.
 

Following the realization that atmospheric effects on signal phase values were significant, a method emerged in the late 1990’s that sought to mitigate this effect by ‘averaging’ data within multiple interferograms. This process was referred to as Interferogram Stacking.

By averaging the data in a stack of interferograms, the signal to noise ratio (SNR) values are enhanced and, theoretically, it is easier to extract information on displacement over longer periods of time than are realistic for single interferogram DInSAR.

However, for this process to be successful, certain assumptions are made:

• Although different versions of this technique exist, the displacement rate of the area of interest is assumed to be constant in time. In reality, such an assumption has limited validity. Multiple interferograms usually describe ground movement over time lines measured in years. Apart from tectonic deformation, linear movement over such time periods is not common.
• The data are heavily filtered, spatially, before the stacking procedure is implemented. Not only does this reduce the resolution but also prompts the loss of potentially valuable data contained in ‘isolated’ pixels with high SNR values, and it also smoothes out abrupt changes in displacement, e.g. seismic faults.
• The atmospheric contribution to signal phase is not estimated. Thereby, no assessment is possible on the quality of the filtering procedure. Atmospheric disturbances are characterized by specific statistical features, and the separation of motion and atmospheric phase components should take into account the peculiarities of the ‘noise’ to be filtered out.
• Typically, stacking procedures are only applied using interferograms with an orbital baseline less than 300m, because of the spatial filtering. As a result, substantial quantities of information that can be found from within interferograms whose baselines are as high as 1300m are overlooked, the latter being a common baseline upper limit for PSI technologies.

While interferogram stacking provides the user with better information than can be obtained from single differential interferograms (DInSAR) the approach is far from optimal, particularly because deformation cannot be considered constant in time. Moreover, for the estimation of atmospheric noise, the procedure usually adopted to produce a weighted average, i.e. to assign different importance to different interferograms, is based on visual inspection of multiple interferograms.

Finally, as already mentioned, the estimation of errors is usually not performed.
 

Persistent Scatterer Interferometry (PSI) is the collective term used within the InSAR community to distinguish between single interferogram DInSAR and the second generation of InSAR technologies, of which there are but a few. The first of these to appear, in 1999, was the PS Technique™, the base algorithm of which is PSInSAR™. It is proprietary to the Politecnico di Milano (Polimi) and licensed exclusively to TRE for commercial development. TRE has no specific knowledge of the competing algorithms; however, in concept they are all likely to be similar in approach, although probably different in their analytical capability. The following description of PSI technology is based on the PSInSAR™ model.

All PSI technologies are advanced forms of DInSAR. In other words, the interferogram is at the core of PSI. The fundamental difference is that PSI technologies develop multiple interferograms from a stack of radar images. As a minimum, 15 radar scenes are usually required for PSI methods, including PSInSAR™, even though there are circumstances when an analysis can be conducted with fewer images (typically in urban areas). However, it should be noted that the more there are radar scenes available, the more accurate will be the results of PSInSAR™, and the same holds true for other PSI methods.

The main driver for the development of PSInSAR™ was the need to overcome the errors introduced into signal phase values by atmospheric artifacts. By examining multiple images, usually a minimum of 15 scenes, many interferograms (in this case 14 interferograms) are generated by selecting one of the scenes as a master to which the other 14 scenes become slaves.

The process by which removal of atmospheric effects is achieved involves searching the imagery and interferograms for pixels that display stable amplitude and coherent phase throughout every image of the data set. They are referred to as Permanent, or Persistent, Scatterers. Thus a sparse grid of point-like targets characterized by high signal to noise ratios (SNR) is identified across an area of interest on which the atmospheric correction procedure can be performed. Once these errors are removed, a history of motion can be created for each target.

Having removed the atmospheric artifacts, the interferometric data that remain are displacement values (resolved along the satellite LOS) plus noise, dependent on the quality (SNR) of the reflector.
 

Error bars of measurement of a PS are calculated as the deformation pattern is developed.  However, precision of the displacement calculations is an important element in validating PS data. The most important factors impacting on data quality are:

• Spatial density of the PS (the lower the density, the higher the error bar)
• Quality of the radar targets (signal-to-noise ratio levels)
• Climatic conditions at the time of the acquisitions
• Distance between the measurement point (P) and the reference (P₀)

Comparable values for the satellites launched during 2007/8 are not yet available since the volume of data from these satellites that has been processed to date is still quite low.  However, it is expected that precision will be improved because a) the sensors on the newer satellites are more sophisticated, and b) the resolution cell sizes are smaller than those of the earlier satellites.

The table below describes the precision values obtained from many analyses of data from the ERS, Envisat, and Radarsat-1 satellites. Typical values of precision (1σ) for a point less than 1 km from the reference point (P₀), considering a multi-year dataset of radar images.