Impact model: HYPE

The HYPE model is a dynamic rainfall–runoff model which describes the hydrological processes at the catchment scale. The model represents processes for snow/ice, evapotranspiration, soil moisture and flow paths, groundwater fluctuations, aquifers, human alterations (reservoirs, regulation, irrigation, abstractions), and routing through rivers and lakes.

HYPE is one of the 15 regional hydrology models following the ISIMIP2a protocol which form the base of simulations for the ISIMIP2a regional water sector outputs; for a full technical description of the ISIMIP2a Simulation Data from Water (regional) Sector, see this DOI link: http://doi.org/10.5880/PIK.2018.007

ISIMIP2b
ISIMIP2a

Confirm data for simulation round ISIMIP2b

Person responsible for model simulations in this simulation round

Ilias Pechlivanidis: ilias.pechlivanidis@smhi.se, 0000-0002-3416-317X, Swedish Meteorological and Hydrological Institute (SMHI) (Sweden)

Additional persons involved: Ilias Pechlivanidis

Output Data

Experiments: I, II, III (all for Mackenzie and Lena)
Climate Drivers: None
Date: 2017-12-04

Basic information

Model Version: HYPE v 4.5.1

Reference Paper: Main Reference: Lindstrom G., Pers C., Rosberg J., Stromqvist J., Arheimer B. et al. Development and testing of the HYPE (Hydrological Predictions for the Environment) water quality model for different spatial scales. Hydrology Research,41,295-319,2010

Reference Paper: Other References: Pechlivanidis I, Arheimer B et al. Large-scale hydrological modelling by using modified PUB recommendations: the India-HYPE case. Hydrology and Earth System Sciences,19,4559-4579,2015
Hundecha Y., Arheimer B., Donnelly C., Pechlivanidis I.G. et al. A regional parameter estimation scheme for a pan-European multi-basin model. Journal of Hydrology: Regional Studies,6,90-111,2016
Andersson J, Ali A, Arheimer B, Gustafsson D, Minoungou B et al. Providing peak river flow statistics and forecasting in the Niger River basin. Physics and Chemistry of the Earth, Parts A/B/C,100,3-12,2017

Resolution

Spatial aggregation: subbasins

Temporal resolution of input data: climate variables: daily

Temporal resolution of input data: land use/land cover: constant

Temporal resolution of input data: soil: constant

Input data

Simulated atmospheric climate data sets used: MIROC5 (rcp45), HadGEM2-ES (rcp45), IPSL-CM5A-LR (rcp45), GFDL-ESM2M (rcp45), IPSL-CM5A-LR, HadGEM2-ES, GFDL-ESM2M, MIROC5

Other data sets used: GRanD reservoirs & dams

Climate variables: ta, pr

Exceptions to Protocol

Exceptions: Consideration of human-impacts on the model setups

Spin-up

Was a spin-up performed?: Yes

Spin-up design: 3 years spin-up

Natural Vegetation

Natural vegetation partition: Depending on the model setup and geographic domain

Natural vegetation dynamics: No dynamics

Natural vegetation cover dataset: CORINE, GLC2000

Management & Adaptation Measures

Management: Reservoir management using information from GLWD and GranD databases

Extreme Events & Disturbances

Key challenges: Based on the performance metrics used and monthly evaluation, the performance is considered acceptable.

Methods

Potential evapotranspiration: Potential evapotranspiration depends on temperature and a seasonal adjustment factor. It is zero for temperatures below a threshold value (as for snow fall and snow melt).

Snow melt: For land classes precipitation is assumed to fall as snow below an air temperature threshold. The air temperature depends on the elevation of the class. For temperatures within an interval around the threshold, a mixture of rain and snowfall is assumed. Snow is accumulated for each land class until melting. Snow melt is calculated with a degree-day method, and uses the same threshold temperature as snowfall. The degree-day parameter depends on land use.

Vegetation

Is co2 fertilisation accounted for?: No

Routing

Runoff routing: Based on topography

Routing data: HydroSHEDS, Hydro1K

Calibration

Was the model calibrated?: Yes

Which years were used for calibration?: E-HYPE Rhine (1985-2000); E-HYPE Tagus (1983-1986); Arctic-HYPE Lena (1987-1994); Arctic-HYPE MacKenzie (1991-2001); Niger-HYPE (1990-2001); India-HYPE (1969-1971)

Which dataset was used for calibration?: WFD

How many catchments were callibrated?: A single catchment at the outlet

Modelled catchments

Modelled catchments: Rhine (at Lobith), Tagus (at Almourol), Lena (at Stolb), MacKenzie (at Arctic Red River), Niger (at Lokoja and Tossaye), Ganges (at Farakka)

Confirm data for simulation round ISIMIP2a

Person responsible for model simulations in this simulation round

Berit Arheimer: berit.arheimer@smhi.se, 0000-0001-8314-0735, Swedish Meteorological and Hydrological Institute (Sweden)

Chantal Donnelly: chantal.donnelly@bom.gov.au, 0000-0002-0086-4453, Bureau of Meteorology, Australia (Australia)

David Gustafsson: David.Gustafsson@smhi.se, 0000-0002-2754-7415, Swedish Meteorological and Hydrological Institute (SMHI) (Sweden)

Yeshewatesfa Hundecha: yeshewatesfa.hundecha@smhi.se, 0000-0002-9225-1485, Swedish Meteorological and Hydrological Institute (SMHI) (Sweden)

Ilias Pechlivanidis: ilias.pechlivanidis@smhi.se, 0000-0002-3416-317X, Swedish Meteorological and Hydrological Institute (SMHI) (Sweden)

Output Data

Experiments: historical (Rhine, Tagus, Niger, Ganges, Lena, Mackenzie)
Climate Drivers: None
Date: 2017-02-20

Basic information

Model Version: The model version depends on the regional application

Reference Paper: Other References: Donnelly C, Andersson J, Arheimer B et al. Using flow signatures and catchment similarities to evaluate the E-HYPE multi-basin model across Europe. Hydrological Sciences Journal,61,255-273,2016
Pechlivanidis I, Arheimer B et al. Large-scale hydrological modelling by using modified PUB recommendations: the India-HYPE case. Hydrology and Earth System Sciences Discussions,12,2885-2944,2015

Resolution

Spatial aggregation: subbasins

Horizontal resolution: depends on region

Additional spatial aggregation & resolution information: Spatial resolution depends on the region, mean area for the European basins is 215 km2, for the Arctic basins is 715 km2, for the Ganges is 800 km2, and for the Niger is 2650 km2.

Temporal resolution of input data: climate variables: daily

Temporal resolution of input data: co2: -

Temporal resolution of input data: land use/land cover: time-constant

Temporal resolution of input data: soil: constant

Input data

Observed atmospheric climate data sets used: WATCH (WFD)

Climate variables: tasmax, tas, tasmin, pr

Spin-up

Was a spin-up performed?: Yes

Spin-up design: Same as in protocol

Natural Vegetation

Natural vegetation partition: we do not include dynamic modelling in the model

Natural vegetation dynamics: we do not include dynamic modelling in the model

Management & Adaptation Measures

Management: Yes

Extreme Events & Disturbances

Key challenges: A good model performance would result in higher confidence on model robustness to reproduce extremes

Methods

Potential evapotranspiration: Priestley-Taylor, modified Hargreaves-Semani and other

Snow melt: Degree-day method or simplified energy approaches

Vegetation

Is co2 fertilisation accounted for?: No

Routing

Runoff routing: Reservoir cascade from ground and surface discharge