3.1. Riegl VZ^®-6000 terrestrial laser scanner

Based on time-of-flight measurement with echo digitization and online waveform processing (RIEGL Laser Measurement Systems, 2013), the Riegl VZ^®-6000 TLS can acquire dense point clouds of the glacier surface by emitting near-infrared laser signals (Fig. 2). The pulse emitted by the laser transmitter reaches the target object, from which it is reflected back to the laser receiver. A referenced point cloud results from the calculation of the two-way travel time of the pulse (t). The longitudinal (θ) and transverse (φ) scanning angles of the instantaneous survey are captured by the TLS internal measurement. The coordinates of the measured object (x, y, z) are presented according to

(1) $$L = \displaystyle{{ct} \over 2}$$

(2) $$\left\{ {\matrix{ {x = L\;cos\; \theta \; cos\; \varphi} \cr {y = L\;cos\; \theta \; sin\; \varphi} \cr {z = L\;sin\; \theta} \cr}} \right.$$

where L is the distance between the laser pulse transmitter and target object, and c is the propagation speed of the laser pulse (RIEGL Laser Measurement Systems, 2014a).

Fig. 2. TLS survey of Urumqi Glacier No. 1 with the Riegl VZ^®-6000 terrestrial laser scanner on 25 April 2015. Lower right corner of the picture was a scanning station, which was fixed using reinforced concrete with a GPS-leveling point.

Traditionally, TLS uses class 1 laser beams (wavelengths ~1500 nm), with low reflectance but high absorption over snow and ice cover, and the scanning distance is limited to a few hundred meters (Deems and others, Reference Deems, Painter and Finnegan2013; Gabbud and others, Reference Gabbud, Micheletti and Lane2015). Riegl VZ^®-6000 uses class 3B laser beams (wavelengths ~1064 nm), so high rates of reflection (80%) from snow- and ice- covered terrain and faster surveys (up to 222 000 measurements s⁻¹) are possible even at long distances (up to 6000 m) with high accuracy and precision (Table 1; RIEGL Laser Measurement Systems, 2014a).

Table 1. Parameters and values of ultra-long-range Riegl VZ^®-6000 terrestrial laser scanner (RIEGL Laser Measurement Systems, 2014a)

3.2. Point cloud data acquisition

In order to quantify geodetic mass balance in detail, four scanning stations with a reinforced concrete structure were installed at the terminus of the glacier (Fig. 1c). Scanning stations T1 and T4 captured the surface point clouds of the west branch and T2 and T3 those of the east branch. On 25 April and 28 May 2015, Riegl VZ^®-6000 measurements of Urumqi Glacier No. 1 were performed with the same survey parameters, nearly coincident with days of direct measurements of mass balance (Table 1). To avoid ground motion and to guarantee data quality, the Riegl VZ^®-6000 was always mounted on a tripod placed on stable bedrock (scanning stations) around the glacier for each scan (Figs 1c, 2). Three-dimensional (3-D) coordinates of the four scanning stations were obtained using the real-time kinematic (RTK) GPS (Unistrong E650). The horizontal and vertical accuracies of RTK survey stations were ±1 cm + 1 ppm × D and ±2 cm + 1 ppm × D, respectively, where ppm is parts per million and D is the distance (km) between base station and mobile station. The coordinated system of RTK measurement data is the World Geodetic System 1984 (WGS84) (Wang and others, Reference Wang2016).

Based on high-accuracy 3-D coordinates of the scanning stations, we can quickly and efficiently realize multi-station scanning point clouds registration (a detailed introduction is provided in Section 3.3). In fieldwork, both the data quality and acquisition time must be considered, so surveying parameters are of crucial importance (Table 1). To avoid range ambiguity and to obtain point clouds of the whole glacier surface, laser pulse repetition rates were set to 50 and 30 kHz for rough and fine scanning, respectively (Table 1). The overlap percentage of each scan was above 30%. Surveying parameters of Urumqi Glacier No. 1 are listed in Table 2.

Table 2. Riegl VZ^®-6000 TLS surveying parameters of Urumqi Glacier No. 1 at the monthly scale

3.3. Point cloud data processing

Point cloud data processing was performed using RiSCAN PRO^® v 1.81 software (RIEGL Laser Measurement Systems, 2014b). This includes:

1. (1) Direct georeferencing. The method uses additional sensors (navigation sensors, total station, etc.) to convert the laser scanner's system (Mukupa and others, Reference Mukupa, Roberts, Hancock and Almanasir2016). We used RTK surveying points of each scanning station to transform the Scanner's Own Coordinate System (SOCS) into a Global Coordinate System (GLCS). The principle can be described as

   (3) $$\overrightarrow {r_g} = \overrightarrow {r_0} + R(k)\overrightarrow {r_s} $$
   (4) $$R(k) = \left[ {\matrix{ {{\rm cos}\;k} & {{\rm sin\;} \;k} & 0 \cr {{\rm sin}\;k} & {{\rm cos\;} \;k} & 0 \cr 0 & 0 & 1 \cr}} \right]$$
   where ${\rm \;} \overrightarrow {r_g} $ is the vector of the target in the GLCS, $\overrightarrow {r_s} $ is the vector of the same target in the SOCS, $\overrightarrow {r_0} $ is the vector of SCOS origin in the GLCS, and k is the azimuth between scanning station and backsight target (Lichti and others, Reference Lichti, Gordon and Tipdecho2005).

2. (2) Point cloud registration (Mukupa and others, Reference Mukupa, Roberts, Hancock and Almanasir2016). The position of each scan was fixed after direct georeferencing. However, due to the influence of orientation, the point clouds of the overlapped regions cannot coincide completely. A multi-station adjustment was performed based on the iterative closest point (ICP) algorithm (Besl and McKay, Reference Besl and McKay1992; Zhang, Reference Zhang1992). The orientation of each scan was iteratively modified to calculate the best fit between the point patches based on least-squares minimization of residuals (Besl and McKay, Reference Besl and McKay1992; Gabbud and others, Reference Gabbud, Micheletti and Lane2015).

3. (3) Point cloud vacuation and filtering. An octree algorithm was applied to the registered scans to generate points with equal spacing to realize point cloud data reduction (vacuation) (Schnabel and Klein, Reference Schnabel and Klein2006; Perroy and others, Reference Perroy, Bookhagen, Asner and Chadwick2010), and a terrain filter was used to remove noise and non-ground points (RIEGL Laser Measurement Systems, 2014b).

3.4. Geodetic mass-balance method

In the ArcGIS10.2 software support, interpolation of the processed point generates regular grids (DEMs), and subtraction of the two DEMs provides glacier surface elevation changes. The geodetic observation method determines volume changes by comparing glacier surface elevations of different time periods (Zemp and others, Reference Zemp2013):

(5) $${\rm \Delta} V = \mathop \sum \limits_{i = 1}^N {\rm \Delta} h_ir_i^2 $$

where N is the number of pixels covering the glacier at the maximum extent, $\triangle h_i{\rm \;} $ is the elevation difference of the two grids at pixel i, and r _i is the pixel size at pixel i.

To estimate glacier mass balance (B _geo), geodetic volume change must be converted to specific mass balance (m w.e.) using

(6) $$\; B_{{\rm geo}} = \displaystyle{{{\rm \Delta} V} \over S}\displaystyle{\rho \over {\rho _{{\rm water}}}}$$

(7) $$S = \displaystyle{{S_{t0} + S_{t1}} \over 2}$$

where ρ is the average density of volume changes, and S is the average glacier area of the two geodetic times, t0 and t1, assuming a linear change (Thibert and others, Reference Thibert, Blanc, Vincent and Lane2008; Zemp and others, Reference Zemp2013), which can be considered unchanged at the monthly scale.

3.5. In situ measurements

The mass-balance observation of Urumqi Glacier No. 1 has been implemented using measured points (ablation stakes and snow pits) (Han and others, Reference Han, Liu, Ding and Jiao2005; Xie and Liu, Reference Xie and Liu2010; Wang and others, Reference Wang, Li, Li, Wang and Yao2014). More than 40 ablation stakes were drilled into the glacier surface evenly at different elevations of the east and west branches using a steam drill (Fig. 1b). The hydrological year (mass-balance year) of Urumqi Glacier No. 1 is defined from the previous September 1 to the next August 31 (Liu and others, Reference Liu, Xie and Wang1997). The glacier is a summer-accumulation-type glacier; summer runs from the beginning of May to early September each year. A spatial distribution of single-point measurements of ablation and accumulation (snow depth and density) was determined by stakes and snow pits at intervals of a month during the summer. The measurements include the stake vertical height above the glacier surface, superimposed ice thickness and the density and thickness of each snow/firn layer at individual stakes. Stake and snow pit heights were converted into mass (w.e.) to calculate single point mass balance (the summation of snow/firn, superimposed ice and glacier ice mass balance) using measured densities of snow and ice (Xie and Liu, Reference Xie and Liu2010). For Urumqi Glacier No. 1, point mass balance can be extrapolated to glacier-wide mass balance using contour-line and isoline methods (Xie and Liu, Reference Xie, Liu, Kovar and Nachtnabel1991).

According to fieldwork in April and May, a larger amount of fresh snow covered the whole glacier surface at the time of TLS measurements (Fig. 2), so we primarily thought about snow/firn mass balance in geodetic method. In order to calculate geodetic mass balance precisely, more than 40 snow pits were dug in the glacier surface to measure the snow density, which were performed on the same days as the TLS survey (Fig. 7a). Interpolation of the snow pits produced a distributed snow density of the glacier surface, which was set as an average density of the volume changes (Eqn (6)).

3.6. Uncertainty assessment

Uncertainties in the TLS-derived geodetic mass balance include systematic or random errors (Zemp and others, Reference Zemp2013), which can be attributed to: (1) point cloud data acquisition errors, including terrain and atmospheric environment (wind and moisture); (2) data processing errors and DEM creation, i.e. registration (multi-station adjustment), point cloud filtering and interpolation of the raster DEM (smoothing terrain information) (Gabbud and others, Reference Gabbud, Micheletti and Lane2015; Hartzell and others, Reference Hartzell, Gadomski, Glennie, Finnegan and Deems2015; Fischer and others, Reference Fischer, Huss, Kummert and Hoelzle2016); and (3) spatial bias of the two DEMs and sampling density of snow and ice (Nuth and kääb, Reference Nuth and Kääb2011; Zemp and others, Reference Zemp2013).

Point clouds of the glacier were captured in sunny, windless weather, so wind- and moisture-induced errors can be minimized. The octree algorithm built the topological relationship of scattered points to reduce the point cloud, in order to preserve terrain information as much as possible. To eliminate spatial bias of the two DEMs, scanning point clouds of April were set as the reference; a relative registration selects the ground control points of the stable terrain to match the point clouds of the two periods.

The uncertainties of the average TLS-derived glacier surface elevation changes for individual glaciers were quantified based on geostatistical analysis methods (Rolstad and others, Reference Rolstad, Haug and Denby2009), and can be approximated by

(8) $${\rm \;} \sigma _{\overline {\Delta h{\rm TLS}}} ^2 = \sigma _{\Delta h{\rm TLS}}^2 \times \displaystyle{{S_{{\rm cor}}} \over {5S}}$$

where S is the glacierized area of the subtracted DEMs, which is really the same as the S defined by Eqn (7) at the monthly scale, S _cor is the area over which there are spatial correction errors in the subtraction of the two DEMs, and we conservatively estimate S _cor = S (Fischer and others, Reference Fischer, Huss, Kummert and Hoelzle2016). σ_ΔhTLS is the standard deviation for TLS-derived bedrock (stable terrain) elevation changes.

According to Huss and others (Reference Huss, Bauder and Funk2009), the uncertainty σ _BTLS in the homogenized mass-balance results from errors in the geodetic mass change:

(9) $$\sigma _{{\rm BTLS}} = \pm \sqrt {{(\overline {{\rm \Delta} h{\rm TLS}} \times \sigma _\rho )}^2 + {(\rho \times {\rm \sigma} _{\overline {\Delta h{\rm TLS}}} )}^2} $$

where σ _ρ is the uncertainty of density. ${\rm \; \;} \overline {\Delta h{\rm TLS}} $ is the mean of TLS-derived geodetic elevation changes and the related uncertainty depends on the accuracy of the two DEMs. Resulting values are listed in Table 2 and illustrated in Section 4.3.