Model:Alpine3D: Difference between revisions

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{{Modeler information
|First name=Mathias
|Last name=Bavay
|Type of contact=Technical contact
|Institute / Organization=WSL/SLF
|Postal address 1=Flüelastrasse 13
|Town / City=Davos Dorf
|Postal code=7260
|State=NO STATE
|Country=Switzerland
|Email address=bavay@slf.ch
|Phone=0814170265
}}
{{Additional modeler information
|Additional first name=Michael
|Additional last name=Lehning
|Additional type of contact=Model developer
}}
{{Model identity
|Model type=Modular
|Categories=Terrestrial
|One-line model description=3D model of alpine surface processes
|Extended model description=Alpine3D is a model for high resolution simulation of alpine surface processes, in particular snow processes. The model can be driven by measurements from automatic weather stations or by meteoro-logical model outputs. The core three-dimensional Alpine3D modules consist of a radiation balance model (which uses a view factor approach and includes shortwave scattering and longwave emission from terrain and tall vegetation) and a drifting snow model solving a diffusion equation for suspended snow and a saltation transport equation. The processes in the atmosphere are thus treated in three dimensions and coupled to a distributed one dimensional model of vegetation, snow and soil model (Snowpack) using the assumption that lateral exchange is small in these media. The model is completed by a conceptual runoff module. The model modules can be run in a parallel mode, using the POP-C++ toolkit, using a grid infrastructure to allow computationally demanding tasks.
Alpine3D is a valuable tool to investigate surface dynamics in mountains and is currently used to investigate snow cover dynamics for avalanche warning and permafrost development and vegetation changes under climate change scenarios. It could also be used to create accurate soil moisture assessments for meteorological and flood forecasting.
}}
{{Model technical information
|Supported platforms=Unix, Linux
|Programming language=Fortran77, C, C++
|Start year development=1997
|Does model development still take place?=Yes
|Model availability=As code, As executable
|Source code availability=Through owner
|Program license type=GPL v3
|OpenMI compliant=No but possible
|CCA component=No but possible
|IRF interface=No but possible
|Memory requirements=several Gbits (depends on the surface that is simulated)
|Typical run time=hours to days
}}
{{Input - Output description
|Describe input parameters=The area to be simulated has to be described (DEM, landuse). The meteorological input data (air temperature, relative humidity, precipitations...) have to be described (units, interpolations types). Some parameters about the model itself must be given (precision of the radiation ray tracing algorithms, characteristic lengths, parameters for a bucket model of runoff...)
|Input format=ASCII
|Describe output parameters=for every grid cell: air and surface temperature, relative humidity, short and long wave radiation, snow height, snow water content, albedo
Global outputs: catchment discharge, surface and subsurface flow
At user defined locations: full snow profiles (temperature profile, grain types, grain sizes, density, water content, liquid water content)
|Output format=ASCII
|Pre-processing software needed?=No
|Post-processing software needed?=No
|Visualization software needed?=Yes
|Other visualization software=any software able to visualize data in a 2D grid
}}
{{Process description model
|Describe processes represented by the model=Alpine3D is a model for high resolution simulation of alpine surface processes, in particular snow processes. The model can be driven by measurements from automatic weather stations or by meteoro-logical model outputs. The core three-dimensional Alpine3D modules consist of a radiation balance model (which uses a view factor approach and includes shortwave scattering and longwave emission from terrain and tall vegetation) and a drifting snow model solving a diffusion equation for suspended snow and a saltation transport equation. The processes in the atmosphere are thus treated in three dimensions and coupled to a distributed one dimensional model of vegetation, snow and soil model (Snowpack) using the assumption that lateral exchange is small in these media. The model is completed by a conceptual runoff module.
|Describe key physical parameters and equations=Snow settling, temperature diffusion, snow saltation and suspension, snow metamorphism, terrain radiation.
|Describe length scale and resolution constraints=The model has been used with cells from 5 meters up to kilometers scale.
|Describe time scale and resolution constraints=The time scale constraints usually comes from the input meteorological data: each time step must be provided with a set of input data.
|Describe any numerical limitations and issues=Overall, the model is very computationally intensive. It is usually ran on a grid or a cluster.
}}
{{Model testing
|Describe available calibration data sets=--
|Describe available test data sets=--
|Describe ideal data for testing=--
}}
{{Users groups model
|Do you have current or future plans for collaborating with other researchers?=The underlying 1D model (SNOWPACK) is already being used by various collaborating researchers/institutions.
}}
{{Documentation model
|Provide key papers on model if any="ALPINE3D: a detailed model of mountain surface processes and its application to snow hydrology", Michael Lehning, Ingo Völksch, David Gustafsson, Tuan Anh Nguyen, Manfred Stähli, Massimiliano Zappa, Hydrological Processes, Volume 20 Issue 10, Pages 2111 - 2128, 8 Jun 2006
|Manual model available=Yes
}}
{{Additional comments model}}
{{Infobox Model
{{Infobox Model
|model name              = Alpine3D
|model name              = Alpine3D

Revision as of 08:46, 19 September 2009

Contact

Name Mathias Bavay
Type of contact Technical contact
Institute / Organization WSL/SLF
Postal address 1 Flüelastrasse 13
Postal address 2
Town / City Davos Dorf
Postal code 7260
State NO STATE
Country Switzerland
Email address bavay@slf.ch
Phone 0814170265
Fax


Name Michael Lehning
Type of contact Model developer
Institute / Organization
Postal address 1
Postal address 2
Town / City
Postal code
State
Country
Email address
Phone
Fax



Alpine3D


Metadata

Summary

Also known as
Model type Modular
Model part of larger framework
Note on status model
Date note status model

Technical specs

Supported platforms
Unix, Linux
Other platform
Programming language

Fortran77, C, C++

Other program language
Code optimized
Multiple processors implemented
Nr of distributed processors
Nr of shared processors
Start year development 1997
Does model development still take place? Yes
If above answer is no, provide end year model development
Code development status
When did you indicate the 'code development status'?
Model availability As code, As executable"As executable" is not in the list (As code, As teaching tool) of allowed values for the "Model availability" property.
Source code availability
(Or provide future intension) 		Through owner"Through owner" is not in the list (Through web repository, Through CSDMS repository) of allowed values for the "Source code availability" property.
Source web address
Source csdms web address
Program license type GPL v3
Program license type other
Memory requirements several Gbits (depends on the surface that is simulated)
Typical run time hours to days


In/Output

Describe input parameters The area to be simulated has to be described (DEM, landuse). The meteorological input data (air temperature, relative humidity, precipitations...) have to be described (units, interpolations types). Some parameters about the model itself must be given (precision of the radiation ray tracing algorithms, characteristic lengths, parameters for a bucket model of runoff...)
Input format ASCII
Other input format
Describe output parameters for every grid cell: air and surface temperature, relative humidity, short and long wave radiation, snow height, snow water content, albedo

Global outputs: catchment discharge, surface and subsurface flow

At user defined locations: full snow profiles (temperature profile, grain types, grain sizes, density, water content, liquid water content)

Output format ASCII
Other output format
Pre-processing software needed? No
Describe pre-processing software
Post-processing software needed? No
Describe post-processing software
Visualization software needed? Yes
If above answer is yes
Other visualization software any software able to visualize data in a 2D grid


Process

Describe processes represented by the model Alpine3D is a model for high resolution simulation of alpine surface processes, in particular snow processes. The model can be driven by measurements from automatic weather stations or by meteoro-logical model outputs. The core three-dimensional Alpine3D modules consist of a radiation balance model (which uses a view factor approach and includes shortwave scattering and longwave emission from terrain and tall vegetation) and a drifting snow model solving a diffusion equation for suspended snow and a saltation transport equation. The processes in the atmosphere are thus treated in three dimensions and coupled to a distributed one dimensional model of vegetation, snow and soil model (Snowpack) using the assumption that lateral exchange is small in these media. The model is completed by a conceptual runoff module.
Describe key physical parameters and equations Snow settling, temperature diffusion, snow saltation and suspension, snow metamorphism, terrain radiation.
Describe length scale and resolution constraints The model has been used with cells from 5 meters up to kilometers scale.
Describe time scale and resolution constraints The time scale constraints usually comes from the input meteorological data: each time step must be provided with a set of input data.
Describe any numerical limitations and issues Overall, the model is very computationally intensive. It is usually ran on a grid or a cluster.


Testing

Describe available calibration data sets --
Upload calibration data sets if available:
Describe available test data sets --
Upload test data sets if available:
Describe ideal data for testing --


Other

Do you have current or future plans for collaborating with other researchers? The underlying 1D model (SNOWPACK) is already being used by various collaborating researchers/institutions.
Is there a manual available? Yes
Upload manual if available:
Model website if any
Model forum / discussion board
Comments


Alpine3D

Introduction

History

Papers

Alpine3D Questionnaire

Contact Information

Model: Alpine3D
Contact person: Mathias Bavay (Technical contact)
Institute: WSL/SLF
City: Davos Dorf
Country: Switzerland
Email: bavay@slf.ch
2nd person involved: Michael Lehning (Model developer)
3rd person involved: --

Model Description

Model type: Modular model for the terrestrial.
Description: Alpine3D is a model for high resolution simulation of alpine surface processes, in particular snow processes. The model can be driven by measurements from automatic weather stations or by meteoro-logical model outputs. The core three-dimensional Alpine3D modules consist of a radiation balance model (which uses a view factor approach and includes shortwave scattering and longwave emission from terrain and tall vegetation) and a drifting snow model solving a diffusion equation for suspended snow and a saltation transport equation. The processes in the atmosphere are thus treated in three dimensions and coupled to a distributed one dimensional model of vegetation, snow and soil model (Snowpack) using the assumption that lateral exchange is small in these media. The model is completed by a conceptual runoff module. The model modules can be run in a parallel mode, using the POP-C++ toolkit, using a grid infrastructure to allow computationally demanding tasks.

Alpine3D is a valuable tool to investigate surface dynamics in mountains and is currently used to investigate snow cover dynamics for avalanche warning and permafrost development and vegetation changes under climate change scenarios. It could also be used to create accurate soil moisture assessments for meteorological and flood forecasting.

Technical information

Supported platforms: UNIX, Linux
Programming language: Fortran77, C, C++
Model development started at: 1997 and development still takes place.
To what degree will the model become available: Source code & executable will be available
Current license type: GPLv3
Memory requirements: several Gbits (depends on the surface that is simulated)
Typical run time: hours to days

Input / Output description

Input parameters: The area to be simulated has to be described (DEM, landuse). The meteorological input data (air temperature, relative humidity, precipitations...) have to be described (units, interpolations types). Some parameters about the model itself must be given (precision of the radiation ray tracing algorithms, characteristic lengths, parameters for a bucket model of runoff...)
Input format: ASCII
Output parameters: for every grid cell: air and surface temperature, relative humidity, short and long wave radiation, snow height, snow water content, albedo

Global outputs: catchment discharge, surface and subsurface flow

At user defined locations: full snow profiles (temperature profile, grain types, grain sizes, density, water content, liquid water content)

Output format: ASCII
Post-processing software (if needed): No
Visualization software (if needed): Yes, any software able to visualize data in a 2D grid

Process description

Processes represented by model: Alpine3D is a model for high resolution simulation of alpine surface processes, in particular snow processes. The model can be driven by measurements from automatic weather stations or by meteoro-logical model outputs. The core three-dimensional Alpine3D modules consist of a radiation balance model (which uses a view factor approach and includes shortwave scattering and longwave emission from terrain and tall vegetation) and a drifting snow model solving a diffusion equation for suspended snow and a saltation transport equation. The processes in the atmosphere are thus treated in three dimensions and coupled to a distributed one dimensional model of vegetation, snow and soil model (Snowpack) using the assumption that lateral exchange is small in these media. The model is completed by a conceptual runoff module.
Key physical parameters & equations: Snow settling, temperature diffusion, snow saltation and suspension, snow metamorphism, terrain radiation.
Length scale & resolution constraints: The model has been used with cells from 5 meters up to kilometers scale.
Time scale & resolution constraints: The time scale constraints usually comes from the input meteorological data: each time step must be provided with a set of input data.
Numerical limitations and issues : Overall, the model is very computationally intensive. It is usually ran on a grid or a cluster.

Testing

Available calibration data sets: --
Available test data sets: --
Ideal data for testing: --

User groups

Currently or plans for collaborating with: The underlying 1D model (SNOWPACK) is already being used by various collaborating researchers/institutions.

Documentation

Key papers of the model: "ALPINE3D: a detailed model of mountain surface processes and its application to snow hydrology", Michael Lehning, Ingo Völksch, David Gustafsson, Tuan Anh Nguyen, Manfred Stähli, Massimiliano Zappa, Hydrological Processes, Volume 20 Issue 10, Pages 2111 - 2128, 8 Jun 2006
Is there a manual available: yes
Model website if any: --

Additional comments

Comments: --

Issues

Help

Input Files

Output Files

Download

Source

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