a. Study area

In this study, we consider the glaciers Guren, Guila, Lisheng, and Bili located on the southern slope of the Nyainqêntanglha range (30°19′0″N, 90°7′50″E). It is a mountain range lying approximately 300 km northwest of Lhasa in central Tibet (Caidong and Asgeir 2010). The ice volume of about 4900 km³ is distributed over 7080 glaciers in this mountain range. Nevertheless, there are only 28 valley glaciers longer than 10 km (Zongtai and Huian 1992; Yao et al. 2007). These glaciers play a significant role in the circulation of the Yarlung Tsangpo and Nu rivers. The study area is limited by elevation ranging from 4498 to 7162 m, and the mean slope is 17.51°. A glacier inventory is a basic tool to explore issues related to glacial studies and morphology studies in glacial areas. Since the 1970s, Chinese scientists have focused on this task through aerial photographs and in situ measurements. The latest Chinese glacier inventory has been a fusion of new topographic maps, digital elevation models (DEMs), optical imagery [Advanced Spaceborne Thermal Emission and Reflection Radar (ASTER) and Landsat Thematic Mapper (TM)/Enhanced TM (ETM)], and historical records. All four glacier outlines used below correspond to the Chinese glacier inventory by Cold and Arid Regions Environmental and Engineering Research Institute (CAREERI), Chinese Academy of Sciences (CAS) described in Shi and Liu (2000) and Shi et al. (2009).

b. ICESat/GLAS data

The ICESat/GLAS instrument consists of two channels, at 1064 nm and 532 nm. The first channel is designed for the measurement of surface topography. There are three lasers on ICESat/GLAS. Laser 1 started to collect data in February 2003, but it failed shortly after its launch. Lasers 2 and 3 have collected data with a number of 33-day subcycle campaigns to increase their longevity. The receiver on GLAS records the echo waveform in 200 bins over sea and 544 (1000) bins over land, depending on which of the two lasers is used, with a beam width of ~110 μrad and a pulse rate of 40 s⁻¹ (Kwok et al. 2006).

The ICESat/GLAS data used in this study were acquired within campaign L2A (September–November 2003), L2B (February–March 2004), L2C (May–June 2004), and L3A (October–November 2004). Among 15 GLAS data products, we investigate the products of Level 1A raw data and Level 2 global land surface elevation data, releases 428 and 429, available from the National Snow and Ice Data Center (NSIDC). The GLAS products used in the assessment are GLA01 (L1A Global Altimetry) and GLA14 (Land Surface Altimetry). The former stores the transmitted and received waveforms from the altimeter while the latter contains land surface elevation, land footprint geolocation, and reflectance, as well as geodetic, instrumental, and atmospheric corrections for range measurements. These two datasets can be linked by the record index and shot number (1–40). A total of 1316 shots is selected for further evaluation in this area. The area illuminated by the ICESat/GLAS pulse will vary significantly during the span of each campaign, over the course of one orbit, and even shot by shot (shown in Fig. 1).

The measurements were performed by ICESat/GLAS laser altimetry in 2003 and 2004. The bold lines indicate the ICESat tracks over the study area, the background is the rendered elevation captured from ASTER GDEM, and the outline of the Nam Co lake mask is taken from MODIS MOD44W water mask. The glacier outlines are cropped from the Chinese Glacier Inventory, CAREERI, CAS.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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The measurements were performed by ICESat/GLAS laser altimetry in 2003 and 2004. The bold lines indicate the ICESat tracks over the study area, the background is the rendered elevation captured from ASTER GDEM, and the outline of the Nam Co lake mask is taken from MODIS MOD44W water mask. The glacier outlines are cropped from the Chinese Glacier Inventory, CAREERI, CAS.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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The measurements were performed by ICESat/GLAS laser altimetry in 2003 and 2004. The bold lines indicate the ICESat tracks over the study area, the background is the rendered elevation captured from ASTER GDEM, and the outline of the Nam Co lake mask is taken from MODIS MOD44W water mask. The glacier outlines are cropped from the Chinese Glacier Inventory, CAREERI, CAS.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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c. ASTER GDEM data

ASTER imagery is captured from a multispectral imaging sensor on board the NASA Terra platform, launched in December 1999. It is designed to monitor surface geodynamic processes, such as glacier movements, landslides, and flood disaster assessment, with higher resolution and better coverage than other previous spaceborne optical instruments. The main spectral and geometric capabilities of the imaging system are three visible and near-infrared (VNIR) bands, six shortwave infrared (SWIR) bands, five thermal infrared (TIR) bands, and one NIR along-track stereo band with 15, 30, 90, and 15-m spatial resolution, respectively (Yamaguchi et al. 1998).

For normal ASTER DEM generation, the stereo band 3B is often combined with 3N images (the same spectral range 0.76–0.86 μm) (Fujisada et al. 2005). After ground control point selection, epipolar image selection, image matching, and geocoding, the final ASTER DEM is established. Then, ASTER DEM standard data products are resampled with 30-m postings and with Z accuracies generally between 10 and 25-m root-mean-square error (RMSE) (Toutin and Cheng 2001).

The version of ASTER Global DEM (GDEM1) in this study was released to the public on 29 June 2009. There are 1.2 million DEM tiles covering land surfaces between 83°N and 83°S latitudes. The general quality is estimated as 20 m at 95% confidence for vertical accuracy and 30 m at 95% confidence for horizontal resolution. Because of the lack of GPS and other sources of ground control points, cloud contamination, and water-masking issues, the DEMs in high-elevation regions like the Nam Co lake and the Nyainqêntanglha range still need to be validated.

a. Slope and roughness derived from ASTER GDEM

To evaluate the GLAS performance over mountainous glacial surfaces of varying relief, slope and roughness values for representative geomorphological terrains in our study area were quantified using ASTER GDEM. These two parameters were defined at a length scale of 90 m, approximating the footprint diameter of the GLAS laser beams by calculating the best-fitting local mean plane to a 3 × 3 grid of elevation values (see Fig. 2). The slope calculation [Eqs. (1)–(5)] used the algorithm described by Burrough et al. 1998:

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where dz/dx and dz/dy are the height change rate of the surface in two orthogonal directions from the center cell. Then we transform the unit of slope from radians to degrees using Eq. (5) (see Fig. 2):

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Example of a moving window. The black ellipse corresponds to one footprint of ICESat illuminating the surface target. Each pixel is 30 m × 30 m, the characters from H₁ to H₉ indicate the magnitude of elevation. Both slope and roughness will be calculated at this moving window scale.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Example of a moving window. The black ellipse corresponds to one footprint of ICESat illuminating the surface target. Each pixel is 30 m × 30 m, the characters from H₁ to H₉ indicate the magnitude of elevation. Both slope and roughness will be calculated at this moving window scale.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Example of a moving window. The black ellipse corresponds to one footprint of ICESat illuminating the surface target. Each pixel is 30 m × 30 m, the characters from H₁ to H₉ indicate the magnitude of elevation. Both slope and roughness will be calculated at this moving window scale.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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The surface roughness can be defined in several different ways, but for consistency with the ICESat/GLAS data, we quantified the roughness from the ASTER GDEM data as the standard deviation of the differences with the locally best-fitting plane as follows. First, the plane P(x, y) best fitting the elevations in the 3 × 3 ASTER GDEM window, in the least squares sense, is estimated, given by

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Then the roughness σ_R is defined as

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with

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All these implementations are done in the commercial software ArcInfo.

b. ICESat full-waveform fitting process

The quality of the full waveform is essential to determine the range from the satellite to the features on the ground. Normally, the emitted pulse is considerably stable and introduces little error in the elevation calculation. However, the echo waveform can be modified by changes in emitted pulse energy, cloud effects, surface reflectivity, and characteristics of the surface illuminated within a single laser footprint (Yi et al. 2005). To shape the features of echo waveforms, we used a waveform-fitting procedure to remove noise. Waveforms were removed from further analysis for one of the following reasons: 1) the raw waveform cannot be decomposed by the Gaussian fitting algorithm or 2) the deviation between ICESat GLA14 and ASTER GDEM is greater than 100 m.

Based on previous waveform studies by the NASA ICESat/GLAS team, the assumption is that the waveform is decomposable as a number of Gaussian components and a noise component (Abshire et al. 2003). In our case, the glaciers of interest are located in a continental summer-precipitation climate. In general, the peaks of the echo waveform represent relevant surface morphological features. Waveform extent is defined as the vertical distance between the first and the last elevation at which the waveform exceeds a threshold level corresponding to the peak and 4 times the standard deviation of the background noise (Abshire et al. 2005). The decomposition of the waveform is formulated as follows:

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where w(t) is the amplitude of the waveform at time t, W_m is the contribution from the m_th Gaussian mode, N_p is the number of Gaussian modes found in the waveform, A_m is the amplitude of the mth Gaussian, t_m is the Gaussian position, σ_m is the 1/e half-width (standard deviation) of the mth Gaussian, and ɛ is the bias (noise level) of the waveform.

The original data from GLA01 is formatted in binary and counts. We converted them to the American Standard Code for Information Interchange (ASCII) and voltage for further processing. In the fitting step, Gaussian components are fitted to the return waveform.

A robust least squares method is used to compute the model parameters. That is, the values of ɛ, A_m, t_m, and σ_m are obtained by fitting the theoretical model to the observed waveform in such a way that the difference between model and observation is minimized in the least squares sense. The parameter's n modes (the number of fitted peaks) and the full-waveform width are generated for further analysis in later sections (Duong et al. 2009). Both of them encode specific physical information: nmodes, the number of waveform peaks, roughly corresponds to the number of elevation levels (including the objects and the earth's surface), and the width of the full waveform represents the elevation range between lowest and highest surface elements within an ICESat/GLAS footprint (Fig. 3).

Demonstration of the waveform width and waveform modes of a typical ICESat/GLAS returned waveform. The red dashed line, the black solid line, and the green solid line represent the raw waveform, the fitted waveform, and the Gaussian components, respectively. Here, the number of modes is 3; the width of full waveform equalizes to about 145 ns corresponding to ~21 m.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Demonstration of the waveform width and waveform modes of a typical ICESat/GLAS returned waveform. The red dashed line, the black solid line, and the green solid line represent the raw waveform, the fitted waveform, and the Gaussian components, respectively. Here, the number of modes is 3; the width of full waveform equalizes to about 145 ns corresponding to ~21 m.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Demonstration of the waveform width and waveform modes of a typical ICESat/GLAS returned waveform. The red dashed line, the black solid line, and the green solid line represent the raw waveform, the fitted waveform, and the Gaussian components, respectively. Here, the number of modes is 3; the width of full waveform equalizes to about 145 ns corresponding to ~21 m.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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c. Theoretical impact of morphology on the ICESat full waveform

In this paragraph the theoretical response of an ICESat waveform on the reflecting terrain is described (Gardner 1982). This theory assumes that the average waveform shape due to terrain reflection is related to the probability density of variation of terrain elevations within the laser footprints. We use the series of equations below, where N is the photon count, T_p is the centroid time of the received pulse, and σ_SR is the RMS pulse width. These are the functions of temporal moments of the pulse, and they are defined as follows:

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where p(t) is the real signal strength. Furthermore, these parameters are proved sensitive for certain statistics of the surface target (Gardner 1992):

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where σ_F is the transmitted laser RMS pulse width; σ_h is the RMS width of receiver impulse response; Var(Δξ) is the RMS roughness parameter of the statistical surface; c is the speed of light; S_x, S_y are the along-track and across-track slope, respectively; q_t is the laser beam divergence angle; and f is the laser-pointing angle off nadir.

For the ICESat/GLAS system, both the pointing uncertainty (1.5 arc sec) and the normal off-nadir pointing angles (<1°) are small; thus, the above equation was simplified as

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From these equations, the laser system contributions to the width of the received pulse include the widths of the transmitted pulse and the receiver impulse response. The received pulse is broadened by the surface roughness and slope of the ground target and by the beam curvature.

The relevant procedures of this study are summarized in a scheme in Fig. 4. Part 1 is mainly about the full-waveform-fitting algorithm. We use the methodology mentioned before to fit all the selected waveforms in the study region. Part 2 aims at comparing the waveform parameters obtained from the fitting procedures to the topographic slope and roughness as obtained from ASTER GDEM.

Processing chain of full-waveform parameter evaluation. It includes two workflows fitting processing and parameter analyses. The raw waveform data of GLA01 is converted to ASCII format, the unit is transferred from count to voltage, and Gaussian modes are fitted using the least squares method in Part I. All these steps were implemented as Interactive Data Language (IDL) and Matlab scripts. Part II comprises waveform parameter extraction, filtering, analysis of a typical example of waveform, and waveform parameter correlation with morphology in this region.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Processing chain of full-waveform parameter evaluation. It includes two workflows fitting processing and parameter analyses. The raw waveform data of GLA01 is converted to ASCII format, the unit is transferred from count to voltage, and Gaussian modes are fitted using the least squares method in Part I. All these steps were implemented as Interactive Data Language (IDL) and Matlab scripts. Part II comprises waveform parameter extraction, filtering, analysis of a typical example of waveform, and waveform parameter correlation with morphology in this region.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Processing chain of full-waveform parameter evaluation. It includes two workflows fitting processing and parameter analyses. The raw waveform data of GLA01 is converted to ASCII format, the unit is transferred from count to voltage, and Gaussian modes are fitted using the least squares method in Part I. All these steps were implemented as Interactive Data Language (IDL) and Matlab scripts. Part II comprises waveform parameter extraction, filtering, analysis of a typical example of waveform, and waveform parameter correlation with morphology in this region.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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a. ICESat full-waveform examples over the study area

Accumulation and ablation zones can be divided into much more specific zones, these being distinct zones with characteristic features in the surface layers of a glacier. As most laser scanning systems are operating in the near-infrared part of the electromagnetic spectrum, some differences on the surface by different surface types, for example, snow, firn, and ice, can be observed.

In the view of glaciomorphology, over 90% of the glaciers in this study area are mountain glaciers. First of all, we set several criteria to describe the morphological characteristics of a glacier: the general shape, the terminus location, the longitudinal profile, supply source of the glacier, and activity of the ice tongue. Moreover, we geolocated the ICESat/GLAS samples on the glaciers using the CAREERI glacier mask. Finally, we pick up four larger glaciers (Guren, Guila, Lisheng, and Bili) to analyze further.

The four named glaciers are close to each other and span an altitude range of 796.5 m on average. Guren glacier (30°12.78′N, 90°14.31′E) lies in a valley, and the orientation of exposed area and ablation zone are both northern. It is a cirque from morphology, whose terminus is debris covered and downhill, and the longitudinal profile is regular down to the foot of the hill and is not very steep. The tongue retreats slowly (Oerlemans and Fortuin 1992; Yao et al. 2007). Guila (30°11.92′N, 90°16.35′E) is located southeast of Guren and is also a valley glacier consisting of multiple basins on the upward side. Its terminal is debris covered, but the longitudinal profile reveals some ice falls, crevasses, and tower-shaped ice; the main source is avalanche and relevant snow. The retreat of the tongue is still not very fast. Lisheng and Bili are mountain glaciers; thus, frontal characteristics are expended. The main mass source of the glacier is the same as for Guren, and the glacier front has retreated slightly.

Mountainous terrain, where topographic relief within a footprint is small compared to landscape sizes, typically yields a multimodal ICESat/GLAS waveform. The intensity is a good indicator for glacial optical properties. Ice, snow, and surface irregularities (mainly crevasses) show a good differentiation in terms of geometry and reflectance. Figures 5a and 5b show shots 34 and 21 geolocated in the accumulation zone of Guila, whose slope and roughness are 9.9°, 1.01 m for shot 34 and 49.5°, 1.54 m for shot 21. The distribution is Gaussian in both cases, shot 34 is fitted with only one main peak, and the amplitudes are both close to 1.2 V. Although the waveform width of shot 21 is broadened by the slope effect and is fitted with three peaks, it still comes from a glacier. We considered two other shots (22 and 26) in the ablation zone of Guila and Lisheng (Figs. 5c,d). The most remarkable feature is their larger widths, about 11.27 and 12.01 m, respectively. There are five peaks in shot 22; the peak of the last Gaussian mode responds to the lower ground surface within the ICESat 70-m footprint. Specifically, the number of peaks in shot 26 is less than six as well, the peak of the last Gaussian mode corresponds to the surface elevation, and the maximum intensity is also much lower than the values in Figs. 5a and 5b. In combination with the glacier inventory by CAREERI and Landsat TM imagery 2003, the waveform can be interpreted as illuminated on the crevasses. Similarly, shot 26 is interpreted as coming from debris overlaying the glacier. We find more oscillations in the return pulse, which involved more morphological features.

Typical waveform examples were picked out over different features: (a),(b) accumulation zone of Guila; ablation zone of (c) Guila and (d) Lisheng; (e) location in the rare mountainous area; and (f) the lake surface. Note that to describe the complexity of bare mountainous area, we set number of modes larger than six, when the specific plotting is implemented in (e).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Typical waveform examples were picked out over different features: (a),(b) accumulation zone of Guila; ablation zone of (c) Guila and (d) Lisheng; (e) location in the rare mountainous area; and (f) the lake surface. Note that to describe the complexity of bare mountainous area, we set number of modes larger than six, when the specific plotting is implemented in (e).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Typical waveform examples were picked out over different features: (a),(b) accumulation zone of Guila; ablation zone of (c) Guila and (d) Lisheng; (e) location in the rare mountainous area; and (f) the lake surface. Note that to describe the complexity of bare mountainous area, we set number of modes larger than six, when the specific plotting is implemented in (e).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Through ICESat track coverage of the four glaciers' analysis, we selected Guila and Guren as the most interesting regions for a case study. Then we generated the distribution of these waveform parameters on both ablation and accumulation zones (see Table 2). The measurements are located in the ablation zone, near the tongue of the glacier, and the air temperature is above pressure freezing point, thus speeding up the melting of glaciers. In this area, there is no snow and possibly also a thin layer of water covering the glacier. Clearly, the reflectivity of this area is lower than surrounding bedrocks. The quantity nmodes is sensitive to the roughness of the surface, and the value of nmodes increased by the roughness of the four named glaciers (1.03 ± 0.04–1.15 ± 0.17 m) is larger than three on average. Then the parameters in glacier and mountainous zones are computed, and the results are shown in Table 3. To link the ICESat waveforms and the morphology further, a total of 1188 points is selected in the mountains.

Table 2.

The waveform shift comparison between ablation zone and accumulation zone in Guila and Guren glaciers. The nmodes and W are chosen in the analysis: nmodes are the number of peaks in each return pulse and W is the width of full waveform (from the beginning to the end).

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Table 3.

The attributes of culled out waveforms in both regions from February 2003 to November 2004.

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b. Comparison of parameters derived from ASTER GDEM and ICESat data

To compare the quality of the ICESat elevations, we make a scatterplot of its elevation against that from ASTER GDEM. It shows a linear trend in Fig. 6a. The differences of elevations between ASTER GDEM and ICESat are also visualized in the histogram in Fig. 6b. In terms of absolute magnitude, it indicates that the accuracy of ICESat elevation is higher (ASTER GDEM Validation Team 2009; Zwally et al. 2002). The largest difference is 126.10 m; the difference is on average around 33.96 ± 18.17 m over all samples.

(a) Correlation in elevation between ICESat and ASTER GDEM; (b) the histogram of deviations obtained from ASTER GDEM elevation subtracts from ICESat elevation. We divide all the differences into 20 bins; the occupancies of variable deviations in different range can be found in this histogram.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Correlation in elevation between ICESat and ASTER GDEM; (b) the histogram of deviations obtained from ASTER GDEM elevation subtracts from ICESat elevation. We divide all the differences into 20 bins; the occupancies of variable deviations in different range can be found in this histogram.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Correlation in elevation between ICESat and ASTER GDEM; (b) the histogram of deviations obtained from ASTER GDEM elevation subtracts from ICESat elevation. We divide all the differences into 20 bins; the occupancies of variable deviations in different range can be found in this histogram.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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The surface features' roughness and slope are chosen as the shaping factor of the waveforms (see Fig. 7). Next, we compute the cumulative histograms of ASTER GDEM roughness and slope compared to the ICESat/GLAS full width of the return waveform (Fig. 8).

(a) Slope (°) and (b) roughness (m) extracted from ASTER GDEM. The bold gray line is the outline of the four larger glaciers, Guren, Guila, Lisheng, and Bili. The values of the calculated slope and roughness are color scaled gradually from low to high.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Slope (°) and (b) roughness (m) extracted from ASTER GDEM. The bold gray line is the outline of the four larger glaciers, Guren, Guila, Lisheng, and Bili. The values of the calculated slope and roughness are color scaled gradually from low to high.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Slope (°) and (b) roughness (m) extracted from ASTER GDEM. The bold gray line is the outline of the four larger glaciers, Guren, Guila, Lisheng, and Bili. The values of the calculated slope and roughness are color scaled gradually from low to high.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Cumulative histograms of the surface slope with the full width of the return waveform. (b) Cumulative histograms of the surface roughness with the full width of the return waveform. The blue line indicates the full width of the return waveform, and the dotted line is the surface slope in (a) and the surface roughness in (b).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Cumulative histograms of the surface slope with the full width of the return waveform. (b) Cumulative histograms of the surface roughness with the full width of the return waveform. The blue line indicates the full width of the return waveform, and the dotted line is the surface slope in (a) and the surface roughness in (b).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Cumulative histograms of the surface slope with the full width of the return waveform. (b) Cumulative histograms of the surface roughness with the full width of the return waveform. The blue line indicates the full width of the return waveform, and the dotted line is the surface slope in (a) and the surface roughness in (b).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Based on the cumulative histograms above, we explore the variability and spreading (or dispersion) of the ASTER GDEM slope and roughness with ICESat/GLAS number of modes and waveform width. Figures 9 and 10 show the scatterplots of the ICESat waveform number of modes and the ICESat waveform width versus the ASTER GDEM slope and roughness, respectively. As expected, both the number of modes and the waveform width increase, on average, with the corresponding ASTER GDEM slope and roughness. Indeed, both surface slope and roughness have a widening effect on the waveform: as the vertical distribution of scatterers increase with both growing slope and roughness, the waveform widens, as there is a greater time difference between return time of the lowest and highest scatterer in the illuminated footprint. The relation between surface slope and roughness versus number of modes is less direct. But clearly, in the high-relief mountainous terrain, the possibility of scattering at different heights contributes to the increase of the number of modes.

The distribution of ASTER GDEM–derived slope and roughness vs number of ICESat waveform modes.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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The distribution of ASTER GDEM–derived slope and roughness vs number of ICESat waveform modes.

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The distribution of ASTER GDEM–derived slope and roughness vs number of ICESat waveform modes.

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The distribution of ASTER GDEM–derived slope and roughness vs width of the full ICESat waveform.

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The distribution of ASTER GDEM–derived slope and roughness vs width of the full ICESat waveform.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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The distribution of ASTER GDEM–derived slope and roughness vs width of the full ICESat waveform.

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c. Analysis of ICESat full-waveform parameters as a function of morphology

In this section, we will measure surface roughness at scales on the order of the footprint size. As described before, the shape of the laser echo pulse reveals much about the topography of the region within the laser footprint. Different elevations within the area of footprint will reflect the light with different travel times, leading to pulse spreading. A height difference of h between two points would result in reflected photons returning with a time difference of 2h/c, c being the speed of light.

Based on the theory in the methodology part, the terrain characteristics (slope S and roughness σ_R) can influence the spreading of the echo pulse shape combined with the RMS width of the receiver impulse response and the RMS laser pulse width.

Here, we use three parameters: σ_SR, the RMS pulse width of the echo ICESat laser signal (nanoseconds); σ_h = 0.425FWHM ≈ 1.7, the RMS width of the receiver impulse response (nanoseconds); and σ_F = 6, the transmitted ICESat laser pulse RMS width (nanoseconds).

In the beginning, we fill the gaps of the σ_SR series by 1D interpolation, caused by attenuation of the filtering procedure. Then, using the simplified expression (Gardner 1992), we set the interpolated σ_SR as initial estimates to optimize the σ_SR by nonlinear least squares robust method. According to this process, all the possible singularities, due to σ_SR being insufficiently large, can be avoided. Therefore, we obtain the final acceptable RMS pulse width of the echo ICESat laser signal, satisfying Eqs. (13) and (14). This can be interpreted as the general relation between the terrain characteristics and returned ICESat laser pulse.

Next, we classify the RMS width observation data into groups based on the slope and roughness, respectively. Specifically, we group the RMS width data into three roughness groups: 0–0.7 m, 0.7–1.0 m, and >1.0 m (see Fig. 11). According to the range of the slope (0°–60°), the data in each group are further grouped in slope subclasses at 10° intervals (see Fig. 12), and nearly all the observations fall into the dashed outlined zone. Then all three different-colored RMS width groups show the approximate increasing trend with the majority of slope. Simultaneously, the average of RMS widths in Fig. 12 shows a slightly increasing trend with each group of the majority of RMS roughness in general, and group 1 (obs 0–0.7 m) and group 2 (obs 0.7–1.0 m) show a little drop in the generally increasing trend. The results may be due to the existing extreme values in the groups and the relatively small number of samples (only 8 in group 1 and 78 in group 2) compared with the other groups.

RMS width of received pulse contributed by total slope and RMS roughness for the ICESat/GLAS system. Each color line represents the series RMS width for certain RMS roughness. Owing to the RMS roughness, all the relevant RMS width observation values are classified in three categories. Green dots show the roughness values that fall into 0 ~ 0.7 m, pink dots show the roughness is in 0.7 ~ 1 m, and red dots show roughness larger than 1 m. The bold curve indicates the mean of each bin (in Fig. 12).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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RMS width of received pulse contributed by total slope and RMS roughness for the ICESat/GLAS system. Each color line represents the series RMS width for certain RMS roughness. Owing to the RMS roughness, all the relevant RMS width observation values are classified in three categories. Green dots show the roughness values that fall into 0 ~ 0.7 m, pink dots show the roughness is in 0.7 ~ 1 m, and red dots show roughness larger than 1 m. The bold curve indicates the mean of each bin (in Fig. 12).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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RMS width of received pulse contributed by total slope and RMS roughness for the ICESat/GLAS system. Each color line represents the series RMS width for certain RMS roughness. Owing to the RMS roughness, all the relevant RMS width observation values are classified in three categories. Green dots show the roughness values that fall into 0 ~ 0.7 m, pink dots show the roughness is in 0.7 ~ 1 m, and red dots show roughness larger than 1 m. The bold curve indicates the mean of each bin (in Fig. 12).

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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This figure shows bold curves, which indicates the mean of each RMS width bin grouped by slope.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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This figure shows bold curves, which indicates the mean of each RMS width bin grouped by slope.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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This figure shows bold curves, which indicates the mean of each RMS width bin grouped by slope.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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In total, the results indicate that the roughness approximately contributes to increasing RMS widths. And it is also shown that there is a dispersion of the RMS width based on roughness at low total slopes from analysis above. But at steep slope zones, RMS widths are insensitive to roughness and increase logarithmically with the slope. In other words, the variation of width caused by roughness is not considerably compared to the change caused by slopes. In general, surface roughness is related to the spreading of the Gaussian pulse. Thus, pulse spreading can be caused by footprint roughness or by footprint-scale sloping. For much of the terrain, the dominant cause of spreading is from roughness rather than from slope (Figs. 11, 12). Furthermore, we use the terrain response function and its variance to calculate the ICESat-derived roughness shown in Fig. 13. Rather large values occur in the ASTER GDEM–derived roughness values. However, there are not such relative larger anomalies found in the ICESat/GLAS–derived roughness. To quantify the changes between these two roughnesses, we compute the deviation between the ICESat-derived roughness and the ASTER GDEM–derived roughness in Fig. 14a. The results show that the ICESat-derived roughness fluctuates from 0.03 to 1.58 m, compared with the ASTER GDEM–derived roughness that varies between 0.15 and 6.87 m. Over 90% of the absolute deviation of these two roughnesses falls between 0 and 2 m. Simultaneously, the possibility density function of the roughness deviation follows a gamma function very well (see Fig. 14b).

Comparison of surface roughness from ASTER GDEM (blue) against the roughness from ICESat/GLAS waveform (black). The two roughness values are in meters.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Comparison of surface roughness from ASTER GDEM (blue) against the roughness from ICESat/GLAS waveform (black). The two roughness values are in meters.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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Comparison of surface roughness from ASTER GDEM (blue) against the roughness from ICESat/GLAS waveform (black). The two roughness values are in meters.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Deviation of the two roughnesses, and the RMSE of this deviation is about 0.61 m. (b) According to the statistical fitting, the absolute deviation of these two roughness distributions nearly follow gamma distribution, and most of the values are limited from 0 to 2 m. All roughness deviations are in meters.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Deviation of the two roughnesses, and the RMSE of this deviation is about 0.61 m. (b) According to the statistical fitting, the absolute deviation of these two roughness distributions nearly follow gamma distribution, and most of the values are limited from 0 to 2 m. All roughness deviations are in meters.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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(a) Deviation of the two roughnesses, and the RMSE of this deviation is about 0.61 m. (b) According to the statistical fitting, the absolute deviation of these two roughness distributions nearly follow gamma distribution, and most of the values are limited from 0 to 2 m. All roughness deviations are in meters.

Citation: Journal of Hydrometeorology 14, 4; 10.1175/JHM-D-12-0130.1

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