International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004 
  
Figure 8. Laser altimetry data of an extreme low-water level in a 
Dutch river. The dry groyne fields are clearly visible in this 
hillshade DEM. 
between both dykes is now at our disposal to compute the 
volumes of the high-water level reservoirs. 
Up to now, the floodplains have been measured by aerial 
photogrammetry. Whether laser altimetry data is useful as input 
for the hydraulic model still needs to be researched, but seems 
to give a positive contribution given this extreme low-water 
level data. Most important for the hydraulic computations are 
the line elements in the floodplain, such as dykes, terrain height 
steps, drainage ditches and hedges. The quality of these items 
derived from the laser data has also to be further investigated. 
6. WATER LEVELS 
A new application of the laser altimetry technique is to measure 
the water level. Some laser systems do receive signals from 
water surfaces, in contrast with the FLI-MAP system which 
does not receive any signal from the water surface, see figure 4. 
The laser strip width decreases compared to land mainly due to 
the reflectivity characteristics of water. These water level 
heights, measured during a high water situation in the river 
including the flooded floodplains, can be used to verify the 
water level forecasting model for the Dutch main rivers. The 
high point density, continuous laser data and the flexibility of 
the system gives advantages above the single point data from 
the water gauges, located every 5-10 kilometres downstream. 
In January 2003 a high water wave was expected in the Dutch 
main rivers (Rhine, Waal and [Jssel). With an airborne platform 
laser data of at least | point per 4 m* was obtained. The quality 
was checked on two ways. A control of height differences 
between overlapping strips and between laser data and 
terrestrial measured ground control fields on dykes was 
performed. For the latter one the mean difference was between 
-5.1 em and 3.6 cm, and the standard deviation ranged from 2.9 
to 6.2 cm for reference areas of approximately 5 x 5 m. 
From the laser data of the water surface a contour map was 
derived showing the details in acceleration and congestion of 
the water, see fig. 9. The red and blue lines are every 5 cm, the 
green lines every cm. The water level gradient going down- 
stream and the cross track gradient in river bends can be 
computed from the laser data. An expected downstream 
gradient in this river is approximately 10 cm per km, and for the 
cross track gradient 2 cm per 100 m. 
Another application is to define the reference surface for 
dredging from the laser data. The water level gradient measured 
during a specific discharge along the river axis is the zero level 
for dredging. Dredging is necessary to keep transport by 
shipping optimal. The gradient line attained from laser data is a 
more realistic representation than using the single point water 
gauge measurements. 
    
   
Figure 9. A contour map obtained from the low water level laser 
data, with an aerial photograph as background. 
Finally, river experts denoted that in shallow water areas the 
water surface contains information about the structure of the 
underlying morphology. This phenomena can be recognized in 
case of extreme low-water in the riverbed and in case of high- 
water in the floodplains. Especially constructions in the 
riverbed and different foreland characteristics result in changes 
of the water level. Even the decrease of the water surface 
around a ship (squat) is visible in the laser data. 
7. WAVE AMPLITUDES 
Another application of laser altimetry is the determination of 
wave amplitude and wavelength. The Transport Research 
Centre of the Ministry of Public Works and Water Management 
is concerned with shipping. Fast ferries are restricted to produce 
little wash, but were still causing problems in some areas such 
as erosion to river shorelines, disturbing waves in recreation 
areas and undesirable motions of moored ships. To understand 
the wash of fast ferries a continuous spatial wash measurement, 
obtained by airborne laser altimetry, will improve this, allowing 
a better prediction in wash models, and checking on wash- 
limits. Most water level measurements are single point time 
series, not giving any information about wave direction and 
ncighbouring water level heights. 
A pilot was carried out to measure the wash of the Huizen- 
Almere fast ferry, moving with constant high speed over 
shallow and deep waters. The Toposys II laser scanner of 
TopoSys GMBH was used by Aerodata International Surveys in 
an airplanc. A challenge in this pilot was tuning the exact time 
of measurement by the airplane of the fast ferry moving at 
constant speed (see fig. 10 for the course of both platforms). 
Communication between cockpit and bridge was essential. 
However, the standard communication frequency canals are 
different for both platforms. Therefore, communication with 
VHF was used. 
laser strip surface airplane 
   
ferry 
Figure 10. Course track and corresponding positioning numbers 
for both platforms. 
  
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