Single-difference interferometry

The geometry of an interferometric SAR is shown in Figure 1. Ihe interferometer acquires two images of the same scene with SARs Located at S₁ and S₂. The first SAR is at altitude H. From S₁ , the range, r₀ . and look angle, θ, to a point on the surface are determined by the ground range, y, and elevation z. The range to the same pohu from the SAR at S₂ . differs from r₀ by Δ. Kora single-pass system, such as TOPSAR (Reference ZenkerZebker and Otbers 1992), two images are acquired simultaneously using separate antennas. In contrast, a repeat-pass interferometer acquires a single image of the same area twice from two nearly repeating orbits or flight lines. The baseline separating the SARs can be expressed In terms of components perpendicular to. B₁₁. and parallel to. B_p. a reference-look direction. A Convenient choice is to let the nominal center-look angle, θ_c. deline the reference-look direction.

Fig. 1. Geometry of an interferometric SAR.

The additional information gained by using an interferometer over a simde SAR is ibe range difference, Δ The range resolution of a typical SAR is not sufficient to measure this difference accurately for topographic mapping, Instead, the range difference is determined from the phase-difference information from the pair of complex SAR images. For a distributed target a pixel in a complex image can be represented as

Where k is the wave number andW₁ is a complex, circular Gaussian random variable (RV) with amplitude A₁ and phase ϕ₁ (Reference Rodroguez and MartinRodriguez and Martin. 1992). Beiause the the modulo-2π phase is uiuformly distributed, a single complex image cannot be used to determine range information.

A complex inlerlcrograin is formed as the product of one complex SAR ¡muge witb lhe complex COiijugule of u Second. A pixel in the inlerferogrtim can be expressed its

The phase of this product is given by

Although ϕ₁ and ϕ₂ are both uniformly distributed, if W₁ and W₂ are correlated their difference, (ϕ₁ — ϕ₂). is not uniformaly distributed (Reference JoughinJoughin. 1995). In fact, the distribution of the phase difference can be quite sharply peaked if the complex images are well correlated.

Even with a narrow phase distribution, the phase difference is still only known modulo 2π A phase-unwrapping algorithm (Reference Golstein, Zebker and WernerGoldstein and others. 1988) must be used to remove the modulo-2π ambiguity. The range difference for repeat-pass iiiterferometry can then be determined using

where ϕ_unwarap denotes the unwrapped interlerometric-phase difference.

For a repeat-pass interferometer, Δ is affected by both topography and any movement of the target between orbits that is directed toward or away from the look direction of the radar. The interferometric phase can be expressed as the sum of motion- and topographs -dependent terms.

The displacement-dependent term is given by

where the subscripts are used to denote the coordinates at the center of the SAR resolution cell during first and second satellite passes. When the effects of motion and topography are separated, ϕ_{;displacement} can be used to estimate ice-sheet motion (Reference Goldstein, Englhardt, Frolich, Kamb and FrolichGoldstein and others. 1993; Reference Joughin, Winbrenner and FahnestockJouglun and others. 1995; Reference Rignot, Jezek and SohnRigiiol and others, 1995).

In order to examine the effect of the baseline on the interferometric phase, the topography-dependent term can be approximated as

Variation in ground range, y. introduces a phase ramp across the interferogram. This ramp can be removed by subtracting the interferogram corresponding to a zero-height surface. For a fixed range. r₀,y and Z are not independent variables and are related by

Applying equation (8) io compute the phase ramp corresponding to a zero-height surface, the elevation-dependent phase variation is given by

This indicates that the sensitivity of the interferometer to topography is proportional to the length of B_n .

Double differencing; to cancel ice-sheet motion

Motion-dependenl phase variation often dominates topography-dependent phase variation in ice-sheet inter-ferograms. The effect of motion must be removed from the interferogram before topography can be estimated. Kwoit and others in press have shown dial die motion dependent phase variation can be cancelled be cancelled interferograms. This technique relies on the assumption dial ice is displaced by the same amount over the periods spanned by two interferograms. In this Case the baseline-independent ϕ_cisplacement terms are identical for each interferogram. If phase ramps are removed from the interferograms, then, applying Equation (5) and (9). these interferograms can be approximated as

and

The two interferograms are differenced to form a double-difference interferogram.

This result is equivalent to a topography-only interferogram with a baseline equal to the difference of the baselines for the single-difference interferograms.

Figure 2 show s an example of double differencing to cancel ice-sheet moiion for interferograms from frame 2169 (see Figure 3 for location). Both single-differerence interferograms are formed using 6 d pairs. These interferograms have not been unwrapped, so die fringes due to the modulo-2π- ambiguity are still present. The interferometric pair shown in Figure 2a was acquired during orbits 3218 and 3304 and has B_n ≈ 2 m. The baseline is small, so this is essentially a motion-only interferogram. Figure 2b shows the interferogram for orbits 3132 and 3218. which has B_n ≈ 183 m. Phase ramps corresponding to zero-height surfaces have been removed from both interferograms, The double-difference interferogram is shown in Figure 2c. The motion-dependent fringes, which are die cause of most of the complexity seen in the single-difference interferograme. are cancelled, leaving only fringes due to topography, The baseline of this topography-only interferogram is approximately 185 m.

Fig. 2. an example of double differencing single-difference iterferogrames from (a)orbits 3218/3304

orbit 3132/3218 to generate

a topography-only interferogram.

Fig. 3. Location of frame 2169 and part of Ihr AOL flight Une from 27 July 1993.

Althought the interferograms in this example have die same temporal baseline, it is not neccssary that both interferograms span the same number of days to cancel motion. For example, the phase of a 3 d interferogram can be doubled. This doubles motion-induced phase variation so that the result can be differenced with a 6 d pair. The baseline of a doubled interferogram is also effectively doubled.

An interferometric pair of complex images must be Correlated to succeed in creating a siugle-dilfference interferogram. To form a double-difference interferogram. however, the constituent single-difference interferograms do not need to be correlated with each other, because much of lhe phase variation from speckle is cancelled when the single-difference interferograms are formed. This means that as long as the motion field does not change, interferograms can be differentced even when separated by long intervals. Nerertheless, correlation between interferograms are in their registration. When interferograms are correlated and die baseline is known, they can he registered with sub-pixel accuracy using the сross-corrclation function computed for one image from each interferometric pair (Reference JoughinJoughin, 1995).

Where dure is no correlation between interferograms the locations of the corner points computed by the SAR processor at the United Kingdom Processing and Archiving Facility (UK-PAF) tue used to register the interferograms (Reference JoughinJoughin. 1995). The accuracy of this method was determined by comparison with the more accurate cross-correlation method for several interferograms that could be registered with both methods. The interferograms used for this lest are separated by intervals of 3, 6 and 15 d. Erors for the corner-point registration method are estimated to be 7.5 m in range and 22.4 m in azimuth. These are relative errors. For comparison, the nominal absolute accuracy of the corner-poinl locations is 50 m (Reference Smith, Wilson and MeadowsSmith and others, 1994).

Study area and interferograms

This section examines DEMs created for the area covered by frame 2169 from track 25 of the ERS-1 SAR during the first and second ice phases. The location of this approximately 100 km by 100 km frame is shown in Figure 3. Four single-difference interferograms were generated using data from six orbits, Table 1 gives the orbit pairs, temporal baselines (time between the acquisition of images in an inlerferometric pair) and ESA baseline estimates (Reference SolaasSolaas, 1994) for the single-difference interferograms. Each interferogram in the table is assigned a number, n that is used for subsequent identification. Interferograms are then denoted as I_n . These interferograms are created using ECRS-1 full-seene, complex images processed ai the UK-PAF. The complex interferograms are multilook-averaged 4 pixels in range by 20 pixels in azimuth to yield a pixel spacing of approximately 80 m. As part of lhe processing, phase ramps corresponding to a zero-height surface tire removed.

The interferograms listed in Table 1 are used m creale six double-difference interferograms, which are identified in Table 2. The sequence of operations and the single-difference interferograms used to from each double-difference result are included in the far leflhand column of Table 2. The baselines in this table are derived from the baseline estimates given in Table 1 There of the double-difference interferograms do not include I₁. For these interferograms registration is performed In cross-correlating one image from each pair after compensation (or the baseline. Because they are separated by 22 months, there is no coherence between I₁ and the other inlerferograms. Asa result., double-differenced pairs that include I₁ are registered using the corner-point registration algorithm mentioned earlier. The complex interferograms are double-differenced by multiplexing one interferogram with die complex conjugate of the other. Phase doubling of a 3 d complex interferogram to match the moiton of a 6 d interferogram. denoted as 2 ×I_n is achieved by multiplying ii with itself. To estimate the baseline, 132 evenly spaced tie points z_t , were extracted from the KMS DEM (personal communication from S. Ekholm. 1994).

DEMs generated directly from die double-difference interferograms have large errors (i.e. a few hundred meters) (Reference JoughinJoughin. 1995), which vary primarily in the azimuth direction. The length scale of these errors is greater than about 15 km. It is likely that these errors are the result of phase irregularities in the complex images from the UK-PAF. We estimate the error by low-pass filtering the difference between die interferogram and a synthetic interferogram created using the KMS DEM. Interfero-grams are corrected by subtracting this estimate of the error (Reference JoughinJoughin, 1995). In the resulting DEM the kilometer-scale information is provided by the interferogram, while the longer-scale information (greater than 16 km) is supplied by the KMS DEM. This is not the ideal solution, however. as it allows long-wavelength errors in the altimetry-derived KMS DEM to be propagated to the interferometrically derived DEM. Further research is needed to establish the cause of the underlying long-wavelength phase errors in the interferograms so that ultimately they can be eliminated without the aid of a supplementary DEM. For now. this correction allows us to proceed with our investigation of interferometrometric estimation of ice-sheet topography.

Analysis of interferometrically derived dems

After correction for long-wavelength errors, the interferograms are used to create a set of six DEMs. These DEMs are averaged together to create a composite DEM. z_a. This DEM is displayed in Figure 4a as a shaded surface with an illumination source directed from above, along the z axis. The topography consists of a gentle slope extending from about 2400m in the top righthand corner to about 1100 in the lower lefthand corner. Kilometer-scale undulations typical of ice-sheet terrain are clearly visible. To belter illustrate these features, Figure 4b shows the DEM as a shaded surface from a vantage-point diretly overhead. The light source is the same as that used in Figure 4a. Visually this enhances the appearance of short-scale undulations, while de-emphasizing the long-scale trend of the slope.

Fig. 4. Shadded surface of the composite DEM for frame 2169. The vantage-point is (a) from the side and (b) from above. The light source is directe from above along the z axis

There are no detailed DEMs for die entire SAR frame to compare with the interferometric DEMs. Instead, differences between the individual DEMs and the composite DEM are examined. Because the error for Z_a is unknown, these differences are measures of DEM consistency rather than accuracy. Nevertheless, it is instructive of examine how the DEMs differ. Accuracy is evaluated by comparision with laser-altimeter data for a single flight line in the nexi sub-section.

Mean and standard deviations of die difference, , are given in lhe second and third columns of Table 3 The mean differences , varies In about ±3 m. Because mean differences should be determined largely by tie-point bias. which is the same for all the DEMs. die variability in these differences should be smaller than observed.

Standard deviations range from moderale to quite large. In general, smaller values correspond to the interferograms with the larger baselines. The differenees are too large to be explained by baseline-estimation error alone (Reference JoughinJoughin, 1995). it is also unlikely that random phase error due to speckle can explain these differences, because the interferogrames have been haviely multilook-averaged. Localized phase-unwrapping errors could increase the error. but only for those parts of the images where Correlation is low. Most of the unwrapping errors are confined to the lower lefthand corner of the frame, where motion is greatest. Elevations are less than 1400 m in this region of the DEM. Phase- unwrapping errors are eliminated from the comparison by computing the standard deviation only for that part of the DEM where elevation is greater than 1400 m. These values, reported in the last column of Table 4. do not show a reduction significant enough to attribute the large values of to errors in phase-unwarapping.

The dffierences between the composite and individual DEMs indicate that there may still he some unanticipated phase error in the interferograms. Shaded surfaces (Fig 5) are useful for observing differences among DEMs. Random phase error due to speckle appears as a high-frequency pattern because it varies independently From pixel in pixel. This error tends to be larger for images with shorter baselines. For example, the shaded surface in Figure 5b is more textured than the surface of the DeM shown in Figure 5a, which corresponds to a much longer baseline. Errors that show up as horizontal lines can be seen in the DEM illustrated in Figure 5 as well as in the DEMs that are not shown. These errors are the result of minor phase discontinuities in the complex SAR images. Neither of these effects is large enough to explain the large Standard deviations.

Fig. 5. Shaded surfaces of individual DEMs generated from interferogram (a) 2 × I₁ — I₃ and 2 × I₂ - I₄

The DEM shown in Figure 5b has structures that appear as long ridges or valleys and extend nearly horizontally most of the way across the frame. In contrast, the DEM in Figure 5a is relatively free of such structures. Many of the other individual DEMs not shown have features with shapes and orientation of the same kind as the features visible in Figure 5b. They are not topographic features, because they differ from DEM to DEM. these “streaks” tend to average out in the composite DEM so that little of this type of structure can be seen in Figure 4.

The phase fluctuations that cause streak error are estimated by subtracting an interferogram simulated using the composite DEM from an individual double-difference interferogram. Phase error estimated in this way for I₂ - I₁ and 2 × I₂ - I₄ are displayed modulo-2π in Figure 6. Althought the estimales of phase error in Figure 6 correspond to magnitudes that have similar baseline lengths, the magnitudes of the streaks in each interferogram differ greatly. Observations of similar estimates from several other interferograms also indicate that Streak intensity is independent of baseline length. The sensitivity ofa DEM to streak and other phase errors is inversely proportional to baseline length. Thus, lhe best DEMs are achieved for interferograms having both low streak error and long baselines. Because the widths of the streaks are of similar scale m ihe topographic undulations, it is difficult to esliniale and remove this error by means of filtering.

Fig. 6. Residual phase after subtracting the effect of topography from phase-corrected interferngrams for (a) I₁ - I₁ (B₁₁ ≈ -106 m), and (b) 2 × I₂ - I₄ (B₁₁ ≈ 118 m).

There are similar streaks in the correlation images for the interferograms. Reference Jezek and RignotJezek and Rignoi (1994) have also obse observed streaks with similar orientation in correlation images from a nearby ERS-1 swath. They have shown that the streaks are related to high-frequency variations of the azimuth registration. The underlying cause of this streak "“noise” is still unknown.

Comparison with laser-altimeter data

The NASA Airborne Oceauographic Lidar (AOL) has made several flights over the Greenland ice sheet. This laser altimeter performs overlapping conical scans about 150 m in diameter. Lighly elevation measurements are made per scan. AOL measurements of ice-sheet elevations are repeatable to within 10 cm (Reference Krabill, Thomas, Martin, Swift and FrederickKrabill and others, 1995, Reference Krabill, Thomas, Jezek, Kuivinen and Manizadein press). Accuracy is on the order of a few centimeters, so comparison with AOL data provides a good estimate of the accuracy of interferometric DEMs.

An AOL flight line from 27 July 1993 crosses the upper righlhand corner of frame 2169 Figure 3 shows the loctition of frame 2169 and the AOL flight line. The portion of the flight line that intersects the SAR frame is 76 km long. The AOL data are subsampled along the center of the scan to obtain measurements with 80 m spacing, which is approximately the pixel spacing of the interferometric DEMs. To allow comparison with interferomctric DEMs, die elevation. latitude and longitude of each point along the profile are converted to the ground-range coordinates of the SAR frame. It might have been possible to obtain more accurate baseline estimates by using lie points from the AOK data. This was not attempted, however, because the goal is to establish die accuracy of DLMs created using the radar-altimetry tie points alone.

The mean, , and standard deviation. , of the difference between the AOK elevations, z_AOl and the mterferoraetrkally derived elevations, , are reported in Table 4. The values of vary from about O m 5 m. The mean dilferenee between die AOK profile and the profile extracted from die KMS DEM is 3.43m. Thus, the mean difference of 3.81 m for the composite DEM is moslly attributable to differences between the AOK profile and KMS DEM. Streak noise prohably contributes to some of the variability in the mean differences directly, and also indirectly through an increase in baseline estimation error.

Standard deviations for the individual DEMs are all in rough agreement with the results from the comparison of composite and individual DEMs (Table 3). Only two of the individual DEMs differ from the AOK data by significantly more than 5 m. The relative accuracy of the composite DEM is 2.56 m. which is almost equal to that of the best individual DEM.

Relative differences in elevation Itır the AOL data, the composite DEM and the best individual DEM are identified by comparing the profiles after subtraction of the average elevation Erom each profile Fig 7. DEM error is largest (about 5 m) for the first 10 km of the profile, but stays below about 2.5 m for the rest of the profile. This comparison demonstrates that it is possible to generale ice-sheets DEMs with relative error of about 2.5 m. Elimination of streak noise and better tie points (i.e. AOL data) should further reduce elevation error.

Error from random-phase noise due to speckle varies nearly independently from pixel to pixel. Therefore, the fairly smooth interferometric profiles indicate that this type of phase noise is a relatively minor source of error. The AOK profile is smooth (i.e.. there is hule vertical variation greater than 1 m) on the scale of the 4 (range) by 20 (azimuth) multilook pixel size, so considerably more multilook averaging could be applied to further reduce what little phase noise there is from speckle.

There may be considerable penetration at C-band (i.e. up to 25 m for dry snow: Reference MätzlerMätzler. 1987), so that the measured surface differs from the actual surface. Any bias created by penetration to a uniform depth will he removed during the baseline estimation procedure, which tends to fis the average height to that of the tie points. spatially varying depth of penetration could cause relative differences between the measured topography and the aetual surface topography. Comparison with AOL data indicates that these differences are less than 2.5 m in the area we have examined, which is in the percolation zone. We have not done a comparison for other snow facies. We penetration is likely quite different. The effect of penetration on interferometric DEM accuracy is a topic that needs further study.

Fig. 7. Comparison of AOL profiles with the composite DEM and with the DEM computed using 2 × I₁ - I₃. Tо illustrate relative differences the mean elevation is subtracted from each profile. Ίhe profile runs from each SE and corresponds to that part of the AOL. flight line illustrated that intersects frame 2169 (Fig,. 3).