The HYCLIC LAB has developed numerous models and modeling frameworks in the field of hydrology, ecohydrology, hydroinformatics and landslides. Some of these models have been included in the national report “RETE DI IDROLOGIA APPLICATA” (Network of Practical Hydrology) realized by the Italian national interuniversity consortium “Consorzio Interuniversitario per l’Idrologia (CINID). In particular, 4 models (i.e., Tri.Mo.Ti.S., Mod.A.Ba., tRIBS-Erosion, a model for the assessment of landslide susceptibility) have been included in 3 different thematic groups (Theme VI: Rainfall-Runoff Models; Theme VII: Water Resources; Theme XI: Landslides, debris flows, and landslide hydrology). SHORT DESCRIPTION OF SOME OUR MODELS: 1) TRIMOTIS - The Tri.Mo.Ti.S (TRInacria Model for mOnthly TIme-Series) is a hydrological model developed within a Collaboration Agreement financed by the Sicily Regional Agency “Autorità di Bacino del Distretto Idrografico della Sicilia” for the ecological classification of rivers by the application of the ISPRA (2011) procedure for the assessment of the Hydrological Alteration Index IARI. The model was originally designed to estimate natural discharge at monthly scale at any section of a river (Pumo et al., 2016) and was successively modified and implemented in a GIS environment (Pumo et al., 2017), in order to create a reliable and comprehensive tool for filling/reconstructing historical hydro-climatic time-series, under natural conditions, at gauged and ungauged sites over a region. Tri.Mo.Ti.S. is a QGIS plug-in based on a tightly coupled GIS and hydrological models framework; once the basin outlet coordinates (any point over the region) and the analysis period are chosen by the user, the Tri.Mo.Ti.S., in a very few time, delimits the corresponding basin, reconstructs monthly time-series for the most relevant hydro-climatic variables at the basin scale (precipitation, temperature, natural runoff, potential and actual evapotranspiration, and soil moisture) and generates corresponding reports and a plots. 2) MODABA - The ModABa (MODel for Annual flow duration curves assessment in ephemeral small BAsins), developed by Pumo et al. (2014), can be thought as a wide mosaic whose tesserae are frameworks, models or conceptual schemes separately developed in different studies and harmoniously interconnected with the final aim of reproducing the annual flow duration curves (FDCs) in intermittent small catchments. Two separated seasons within the hydrological year are distinguished: a dry season, characterized by absence of streamflow, and a non-zero season. Streamflow is disaggregated into a subsurface component and a surface component that, in turn, is considered formed by two different contributions: impervious runoff and surface runoff from permeable areas induced by heavy rains. The FDCs of the two streamflow components are first separately and differently computed, and then combined to obtain the non-zero FDC. This last, together with the estimated probability of null streamflow, allows the annual FDC assessment through the theory of total probability. 3) The EHSM (Ecohydrological Streamflow Model) is numerical rainfall-runoff model with lumped parameters. The hydrological scheme of the model is constituted by 3 interconnected elements that are a soil bucket and 2 linear reservoirs. The first reservoir simulates the surface component and is characterized by a residence time in the order of the mean concentration time of the basin (subdaily), while the second, with longer residence times (weeks or even months) models the subsurface components. The bucket is constituted by the root zone, and distinguishes between the pervious and the impervious portion of the basin. The EHSM requires the calibration of a total of 7 parameters, so it can be actually considered as a rather parsimonious model. The model was tested in a Sicilian basin (Eleuterio river basin), investigating parameters uncertainty and equifinality, and its ability in reproducing empirical values. The EHSM was also used in another work, published in Science of the Total Environment in 2016, to evaluate some effects of climate change. A modified version of the model, named EHSMu (EcoHydrological Streamflow Model for Urban areas) was also developed for hourly discharge simulations under ecohydrological framework in urban areas.