HBV-Lab 0.2.2

An intuitive, object-oriented and user-friendly Python implementation of a lumped conceptual HBV hydrological model for educational and research purposes.

HBV_Lab (Python implementation of a lumped conceptual HBV model)

HBV is a simple conceptual hydrological model that simulates the main hydrological processes related to snow, soil, groundwater, and routing [1]. There are many software packages and off-the-shelf products that implement different versions of it [2] [3].

I've been experimenting with the model lately and—in an endeavour to better understand the logic behind it—I decided to implement my own version—in Python, following an intuitive object-oriented programming approach.

This versioin implements the snow, soil, response and routing routines—controled by 14 calibratable parameters as shown below. In addition to calibration and uncertainty analysis modules.

parameters   = {
                  'snow':        ['TT', 'CFMAX', 'SFCF', 'CFR', 'CWH'],
                  'soil':        ['FC', 'LP', 'BETA'],
                  'response':    ['K0', 'K1', 'K2', 'UZL', 'PERC']
                  'routing' :    [ 'MAXBAS'],
               }

This can be flexibly used for different modelling tasks, but can also be used in a classroom setup—to explain hydrological concepts (processes, calibration, uncertainty analysis, etc.).

Get Started

Install the Package

pip install HBV_Lab

How to Use

It is very intuitive—you create a model like an object which has attributes (data, parameters, initial conditions, etc.) that you can assign and access. The object also performs functions (calibration, uncertainty estimation, save, load, etc.)

from HBV_Lab import HBVModel
model = HBVModel()
model.load_data("pandas dataframe")
model.set_parameters(params)
model.run()
model.calibrate()
model.evaluate_uncertainity()
model.plot_results()
model.save_results()
model.save_model("path")
model.load_model("path")

Tutorial

Start by following a simple case study in the notebook: quick_start_guide.ipynb

Play with HBV

Get a feeling of how HBV model work and the role of the different parameters in HBVLAB (which uses a model developed with this HBV implementation).

References

[1] Bergström, S., & Forsman, A. (1973). DEVELOPMENT OF A CONCEPTUAL DETERMINISTIC RAINFALL-RUNOFF MODEL. Hydrology Research, 4, 147-170.

[2] Seibert, J. and Vis, M. J. P.: Teaching hydrological modeling with a user-friendly catchment-runoff-model software package, Hydrol. Earth Syst. Sci., 16, 3315–3325, https://doi.org/10.5194/hess-16-3315-2012, 2012.

[3] AghaKouchak, A., Nakhjiri, N., and Habib, E.: An educational model for ensemble streamflow simulation and uncertainty analysis, Hydrol. Earth Syst. Sci., 17, 445–452, https://doi.org/10.5194/hess-17-445-2013, 2013.