CSDMS - User contributions [en]

Meeting:Abstract 2011 CSDMS meeting-088

2011-10-07T12:27:52Z

Abarkwith:

{{#ifeq:{{#expr:{{#time: U}}>{{#expr:
{{#expr:{{#switch: {{#sub:{{REVISIONTIMESTAMP}}|4|-8}}
| 7 = 1309478400
| 8 = 1312156800
| 9 = 1314835200
| 10 = 1317427200
}} + {{#expr:{{#sub:{{REVISIONTIMESTAMP}}|6|-6}}*24*3600}} + {{#expr:{{#sub:{{REVISIONTIMESTAMP}}|8|-4}}*3600}} + {{#expr:{{#sub:{{REVISIONTIMESTAMP}}|10|-2}} *60}} + {{#sub:{{REVISIONTIMESTAMP}}|12}} -64800}}+30 }} }}|1|{{CSDMS meeting 2011 paid}}|{{CSDMS meeting 2011 not paid}} }}<br>

{{CSDMS meeting personal information template
|CSDMS meeting first name=Andrew
|CSDMS meeting last name=Barkwith
|CSDMS meeting institute=British Geological Society (BGS)
|CSDMS meeting city=Nottingham
|CSDMS meeting state=NO STATE
|CSDMS meeting country=UK
|CSDMS meeting email address=andr3@bgs.ac.uk
|CSDMS meeting phone=--
}}
{{CSDMS meeting abstract yes no
|CSDMS meeting abstract submit=No
}}
{{CSDMS meeting abstract title template}}
{{CSDMS meeting abstract template}}
{{blank line template}}
{{CSDMS meeting program template1
|CSDMS meeting first day choice=CEM
|CSDMS meeting second day choice=CHILD
|CSDMS meeting third day choice=TauDEM
}}
{{CSDMS meeting logistics template
|Attend all days=Yes
|CSDMS arrange hotel=Yes
|Check in date=2011/10/28
|Check out date=2011/10/30
|Share a room=Yes
|CSDMS meeting dinner=No
|CSDMS meeting additional information=Albert added this person to the list
}}

Meeting:Abstract 2011 CSDMS meeting-088

2011-10-07T12:24:05Z

Abarkwith:

{{#ifeq:{{#expr:{{#time: U}}>{{#expr:
{{#expr:{{#switch: {{#sub:{{REVISIONTIMESTAMP}}|4|-8}}
| 7 = 1309478400
| 8 = 1312156800
| 9 = 1314835200
| 10 = 1317427200
}} + {{#expr:{{#sub:{{REVISIONTIMESTAMP}}|6|-6}}*24*3600}} + {{#expr:{{#sub:{{REVISIONTIMESTAMP}}|8|-4}}*3600}} + {{#expr:{{#sub:{{REVISIONTIMESTAMP}}|10|-2}} *60}} + {{#sub:{{REVISIONTIMESTAMP}}|12}} -64800}}+30 }} }}|1|{{CSDMS meeting 2011 paid}}|{{CSDMS meeting 2011 not paid}} }}<br>

{{CSDMS meeting personal information template
|CSDMS meeting first name=Andrew
|CSDMS meeting last name=Barkwith
|CSDMS meeting institute=British Geological Society (BGS)
|CSDMS meeting city=Nottingham
|CSDMS meeting state=NO STATE
|CSDMS meeting country=UK
|CSDMS meeting email address=andr3@bgs.ac.uk
|CSDMS meeting phone=--
}}
{{CSDMS meeting abstract yes no
|CSDMS meeting abstract submit=No
}}
{{CSDMS meeting abstract title template}}
{{CSDMS meeting abstract template}}
{{blank line template}}
{{CSDMS meeting program template1
|CSDMS meeting first day choice=CEM
|CSDMS meeting second day choice=CHILD
|CSDMS meeting third day choice=TauDEM
}}
{{CSDMS meeting logistics template
|Attend all days=No
|CSDMS arrange hotel=No
|Check in date=2011/10/28
|Check out date=2011/10/30
|Share a room=Yes
|CSDMS meeting dinner=No
|CSDMS meeting additional information=Albert added this person to the list
}}

User:Abarkwith

2011-10-05T09:29:51Z

Abarkwith:

{{Signup information member
|First name member=Andrew
|Last name member=Barkwith
|Institute member=BGS
|Department member=Mathematical Modelling
|Postal address 1 member=Kingsley Dunham Centre
|Postal address 2 member=Keyworth
|City member=Nottinghamshire
|Postal code member=NG12 5GG
|State member=NO STATE
|Country member=UK
|Confirm email member=andr3@bgs.ac.uk
|Work phone member=01159363175
|Working group member=Terrestrial Working Group, Coastal Working Group, Hydrology Focus Research Group
|Description of your CSDMS-related interests member=Terrestrial
Currently managing the Dynamic Environment Sensitivity to Climate Change (DESC) project, which seeks to create a modelling platform where the influence of predicted future climate scenarios can be tested on a variety of landscape evolutionary processes at a range of spatio-temporal scales. The current DESC modelling platform is based on the Cellular Automaton Evolutionary Slope And River (CAESAR) model, which can simulate morphological changes in river catchments or reaches, on a flood by flood basis over periods of an hour up to several thousands of years. Through the coupling of the quasi three dimensional groundwater model ZOOMQ3D to CAESAR it was shown that although the cumulative sediment output at the base of a catchment is similar to a non-groundwater simulation, the spatio-temporal distribution of erosion and deposition throughout the modelled area was modified, being influenced through the interplay of rainfall events and groundwater maxima and minima. The coupled model is however, computationally expensive and labour intensive; therefore the groundwater model is currently being replaced by simple subsurface flow algorithms. To further improve hydrological representation and increase the number of novel applications, modification of the surface routing algorithms and inclusion of soil characteristics, evapotranspiration and land use are being undertaken, with dynamic vegetation and improvements to landslide development being added in the near future. When complete, the model will be used to simulate the effects of different climate scenarios on a variety of environments.

Coastal

In the UK, much of the coastal observation, modelling and risk-mitigation work to date has focussed on relatively local domains. CARE, the dynamic coastal evolution project, aims to generate an OpenMI-compliant modelling system that integrates geology, geomorphology and climate, and is focussed on longer time and larger length scales in order to understand better the geomorphological effects of steadily evolving climate regimes. Although this project is in its initial stages, a loose model framework has been created which provides a flexible quasi three-dimensional environment where coastal sediment transport algorithms can be evaluated for a particular study area. Although the framework uses a simple PDF to drive wave climates, in the future running simulations with observed or perturbed wave climate data will open up a number of possible paths including: hind-casting, storm influences, and possible future coastal scenarios.
}}

User:Abarkwith

2011-10-05T09:23:54Z

Abarkwith:

{{Signup information member
|First name member=Andrew
|Last name member=Barkwith
|Institute member=BGS
|Department member=Mathematical Modelling
|Postal address 1 member=BGS Keyworth
|City member=Nottinghamshire
|Postal code member=NG12 5GG
|State member=NO STATE
|Country member=UK
|Confirm email member=andr3@bgs.ac.uk
|Work phone member=01159363175
|Working group member=Terrestrial Working Group, Coastal Working Group, Hydrology Focus Research Group
|Description of your CSDMS-related interests member=Terrestrial
Currently managing the Dynamic Environment Sensitivity to Climate Change (DESC) project, which seeks to create a modelling platform where the influence of predicted future climate scenarios can be tested on a variety of landscape evolutionary processes at a range of spatio-temporal scales. The current DESC modelling platform is based on the Cellular Automaton Evolutionary Slope And River (CAESAR) model, which can simulate morphological changes in river catchments or reaches, on a flood by flood basis over periods of an hour up to several thousands of years. Through the coupling of the quasi three dimensional groundwater model ZOOMQ3D to CAESAR it was shown that although the cumulative sediment output at the base of a catchment is similar to a non-groundwater simulation, the spatio-temporal distribution of erosion and deposition throughout the modelled area was modified, being influenced through the interplay of rainfall events and groundwater maxima and minima. The coupled model is however, computationally expensive and labour intensive; therefore the groundwater model is currently being replaced by simple subsurface flow algorithms. To further improve hydrological representation and increase the number of novel applications, modification of the surface routing algorithms and inclusion of soil characteristics, evapotranspiration and land use are being undertaken, with dynamic vegetation and improvements to landslide development being added in the near future. When complete, the model will be used to simulate the effects of different climate scenarios on a variety of environments.

Coastal

In the UK, much of the coastal observation, modelling and risk-mitigation work to date has focussed on relatively local domains. CARE, the dynamic coastal evolution project, aims to generate an OpenMI-compliant modelling system that integrates geology, geomorphology and climate, and is focussed on longer time and larger length scales in order to understand better the geomorphological effects of steadily evolving climate regimes. Although this project is in its initial stages, a loose model framework has been created which provides a flexible quasi three-dimensional environment where coastal sediment transport algorithms can be evaluated for a particular study area. Although the framework uses a simple PDF to drive wave climates, in the future running simulations with observed or perturbed wave climate data will open up a number of possible paths including: hind-casting, storm influences, and possible future coastal scenarios.
}}

User:Abarkwith

2011-10-05T09:23:24Z

Abarkwith:

{{Signup information member
|First name member=Andrew
|Last name member=Barkwith
|Institute member=BGS
|Department member=Mathematical Modelling
|Postal address 1 member=BGS Keyworth
|City member=Nottinghamshire
|Postal code member=NG12 5GG
|State member=NO STATE
|Country member=UK
|Confirm email member=andr3@bgs.ac.uk
|Work phone member=01159363175
|Working group member=Terrestrial Working Group, Coastal Working Group, Hydrology Focus Research Group
|Description of your CSDMS-related interests member=Terrestrial
Currently managing the Dynamic Environment Sensitivity to Climate Change (DESC) project, which seeks to create a modelling platform where the influence of predicted future climate scenarios can be tested on a variety of landscape evolutionary processes at a range of spatio-temporal scales. The current DESC modelling platform is based on the Cellular Automaton Evolutionary Slope And River (CAESAR) model, which can simulate morphological changes in river catchments or reaches, on a flood by flood basis over periods of an hour up to several thousands of years. Through the coupling of the quasi three dimensional groundwater model ZOOMQ3D to CAESAR it was shown that although the cumulative sediment output at the base of a catchment is similar to a non-groundwater simulation, the spatio-temporal distribution of erosion and deposition throughout the modelled area was modified, being influenced through the interplay of rainfall events and groundwater maxima and minima. The coupled model is however, computationally expensive and labour intensive; therefore the groundwater model is currently being replaced by simple subsurface flow algorithms. To further improve hydrological representation and increase the number of novel applications, modification of the surface routing algorithms and inclusion of soil characteristics, evapotranspiration and land use are being undertaken, with dynamic vegetation and improvements to landslide development being added in the near future. When complete, the model will be used to simulate the effects of different climate scenarios on a variety of environments.

Coastal
In the UK, much of the coastal observation, modelling and risk-mitigation work to date has focussed on relatively local domains. CARE, the dynamic coastal evolution project, aims to generate an OpenMI-compliant modelling system that integrates geology, geomorphology and climate, and is focussed on longer time and larger length scales in order to understand better the geomorphological effects of steadily evolving climate regimes. Although this project is in its initial stages, a loose model framework has been created which provides a flexible quasi three-dimensional environment where coastal sediment transport algorithms can be evaluated for a particular study area. Although the framework uses a simple PDF to drive wave climates, in the future running simulations with observed or perturbed wave climate data will open up a number of possible paths including: hind-casting, storm influences, and possible future coastal scenarios.
}}

User:Abarkwith

2011-10-05T09:22:49Z

Abarkwith:

{{Signup information member
|First name member=Andrew
|Last name member=Barkwith
|Institute member=BGS
|Department member=Mathematical Modelling
|Postal address 1 member=BGS Keyworth
|City member=Nottinghamshire
|Postal code member=NG12 5GG
|State member=NO STATE
|Country member=UK
|Confirm email member=andr3@bgs.ac.uk
|Work phone member=01159363175
|Working group member=Terrestrial Working Group, Coastal Working Group, Hydrology Focus Research Group
|Description of your CSDMS-related interests member=Terrestrial
Currently managing the Dynamic Environment Sensitivity to Climate Change (DESC) project, which seeks to create a modelling platform where the influence of predicted future climate scenarios can be tested on a variety of landscape evolutionary processes at a range of spatio-temporal scales. The current DESC modelling platform is based on the Cellular Automaton Evolutionary Slope And River (CAESAR) model, which can simulate morphological changes in river catchments or reaches, on a flood by flood basis over periods of an hour up to several thousands of years. Through the coupling of the quasi three dimensional groundwater model ZOOMQ3D to CAESAR it was shown that although the cumulative sediment output at the base of a catchment is similar to a non-groundwater simulation, the spatio-temporal distribution of erosion and deposition throughout the modelled area was modified, being influenced through the interplay of rainfall events and groundwater maxima and minima. The coupled model is however, computationally expensive and labour intensive; therefore the groundwater model is currently being replaced by simple subsurface flow algorithms. To further improve hydrological representation and increase the number of novel applications, modification of the surface routing algorithms and inclusion of soil characteristics, evapotranspiration and land use are being undertaken, with dynamic vegetation and improvements to landslide development being added in the near future. When complete, the model will be used to simulate the effects of different climate scenarios on a variety of environments.

Coastal
In the UK, much of the coastal observation, modelling and risk-mitigation work to date has focussed on relatively local domains. CARE, the dynamic coastal evolution project, aims to generate an OpenMI-compliant modelling system that integrates geology, geomorphology and climate, and is focussed on longer time and larger length scales in order to understand better the geomorphological effects of steadily evolving climate regimes. Although this project is in its initial stages, a loose model framework has been created which provides a flexible quasi three-dimensional environment where coastal sediment transport algorithms can be evaluated for a particular study area. Although the framework uses a simple PDF to drive wave climates, in the future running simulations with observed or perturbed wave climate data will open up a number of possible paths including: hind-casting, storm influences, and possible future coastal scenarios.

}}

File:ZOOMQ3D IR 04 140.pdf

2010-03-11T15:26:38Z

Abarkwith: ZOOMQ3D User Manual

ZOOMQ3D User Manual

User:Abarkwith

2010-03-11T14:47:27Z

Abarkwith:

{{Signup information member
|First name member=Andrew
|Last name member=Barkwith
|Institute member=BGS
|Department member=Mathematical Modelling
|Postal address 1 member=BGS Keyworth
|City member=Nottinghamshire
|Postal code member=NG12 5GG
|State member=NO STATE
|Country member=UK
|Confirm email member=andr3@bgs.ac.uk
|Work phone member=01159363175
|Working group member=Terrestrial Working Group, Cyberinformatics and Numerics Working Group
|Focus research group member=Hydrology Focus Research Group
}}