This paper presents a comparative analysis between rain-gauge storm tracking techniques in order to achieve
a better knowledge of the rainfall dynamics over an urbanized area. The temporal and spatial distribution and
kinematics of short term rainfall are recognized as one of the most important reasons in error production in
rainfall-runoff on urban catchments. The uncertainty due to rainfall variability can greatly affect urban drainage
modeling performance and reliability thus reducing the confidence of operators in their results. Modeling
representations of urban catchments and drainage systems are commonly adopted for surface flooding forecasting
and management and an adequate knowledge of rainfall spatial and temporal variability should be
considered as a fundamental step for a robust interpretation of the physical processes that take part in urban
areas during intense rainfall events. The starting basis of such studies is usually given by a network of high
resolution raingauges disseminated inside and around the examined urban area. One of the raingauge techniques
used is based on simulating the storm motion by visualizing the sequence of the rainfall patterns obtained
using rain-gauge data and on spatial correlation. The storm speed and direction are obtained using the
rain-gauge method by tracking the advance of the maximum rainfall intensity in time and space. A second
method is based on the identification, for each gauge, of the time of occurrence of some significant features
such the time of onset of a storm or the time of peak. A third method is based on the classical idea of spacetime
autocorrelation function; This function describes the way in which the correspondence between the
rainfall patterns at two points in space-time reduces as the distance between two points is increased.
The analysis has been carried out on the basis given by high resolution rainfall data collected over Palermo
urban area (Italy). The urban area has a surface of around 30 km2 and it is mainly distributed on North West
– South East direction. The monitoring network is made of 10 tipping bucket raingauges. Bucket volume is
equivalent to 0.1 mm rainfall.
Raingauges have been uniformly distributed over the urban areas allocating them mainly over public buildings
and school in order to allow for easy access. The network has been put in place in January 2006 and it is
still working. Data is monthly collected by the operator that also provide for clock synchronization and ordinary
maintenance and cleaning.
An accurate analysis of the results of this comparison between the techniques has been carried out and, since
the city of Palermo is not covered by any meteorological radar, the analysis of storm dynamics will allow to
create a system monitoring hydrometeorological conditions which operates on time basis using the information
coming from the raingauge network as forecast triggers