Hydrology Models

These models and simulations have been tagged “Hydrology”.

An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
This model uses simple functions (converters, cosine) to simulate the water balance inside a reservoir.
This model uses simple functions (converters, cosine) to simulate the water balance inside a reservoir.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
 A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching
A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching the soil. The remaining rainfall (throughflow) either infiltrates the soil or, if the soil has insufficient capacity, runs off immediately. Soil water exceeding the field capacity is lost by sub-surface leakage, at a rate determined by the degree of soil saturation. Degree of soil saturation also limits rates of soil evaporation and vegetation transpiration. The partitioning between evaporation and transpiration is influenced by fractional area covered by vegetation.

Reference:
Guswa, A.J., Celia, M.A., Rodriguez-Iturbe, I. (2002) Models of soil moisture dynamics in ecohydrology: a comparative study. Water Resources Research 38, 5-1 - 5-15.
7 months ago
 A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching
A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching the soil. The remaining rainfall (throughflow) either infiltrates the soil or, if the soil has insufficient capacity, runs off immediately. Soil water exceeding the field capacity is lost by sub-surface leakage, at a rate determined by the degree of soil saturation. Degree of soil saturation also limits rates of soil evaporation and vegetation transpiration. The partitioning between evaporation and transpiration is influenced by fractional area covered by vegetation.

Reference:
Guswa, A.J., Celia, M.A., Rodriguez-Iturbe, I. (2002) Models of soil moisture dynamics in ecohydrology: a comparative study. Water Resources Research 38, 5-1 - 5-15.
7 months ago
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".   References  Garcia, M., Portney, K., and Islam, S. (2016). A 
question driven
An implementation of the reservoir operations model of Garcia et al. (2016), which seeks to answer the question "what is the impact of reservoir operations policy on the reliability of water supply for a growing city?".

References

Garcia, M., Portney, K., and Islam, S. (2016). A question driven socio-hydrological modeling process, Hydrol. Earth Syst. Sci., 20:73-92, doi:10.5194/hess-20-73-2016.
 A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching
A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching the soil. The remaining rainfall (throughflow) either infiltrates the soil or, if the soil has insufficient capacity, runs off immediately. Soil water exceeding the field capacity is lost by sub-surface leakage, at a rate determined by the degree of soil saturation. Degree of soil saturation also limits rates of soil evaporation and vegetation transpiration. The partitioning between evaporation and transpiration is influenced by fractional area covered by vegetation.

Reference:
Guswa, A.J., Celia, M.A., Rodriguez-Iturbe, I. (2002) Models of soil moisture dynamics in ecohydrology: a comparative study. Water Resources Research 38, 5-1 - 5-15.
6 last week
 A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching
A 'leaky bucket' soil moisture model, based on Guswa et al. (2002). Rain falls as discrete events. The mean depth and frequency of rainfall events are determined by total monthly rainfall and number of rain days. A portion of the rainfall is intercepted by vegetation and evaporates before reaching the soil. The remaining rainfall (throughflow) either infiltrates the soil or, if the soil has insufficient capacity, runs off immediately. Soil water exceeding the field capacity is lost by sub-surface leakage, at a rate determined by the degree of soil saturation. Degree of soil saturation also limits rates of soil evaporation and vegetation transpiration. The partitioning between evaporation and transpiration is influenced by fractional area covered by vegetation.

Reference:
Guswa, A.J., Celia, M.A., Rodriguez-Iturbe, I. (2002) Models of soil moisture dynamics in ecohydrology: a comparative study. Water Resources Research 38, 5-1 - 5-15.