The Design Document page provides a description of the algorithms, implementation and planned testing including unit, verification, validation and performance testing. Please read Step 1.3 Performance Expectations that explains feature documentation requirements from the performance group point of view.
Design Document
In the table below 4.Equ means Equations and Algorithms, 5.Ver means Verification, 6.Perf - Performance, 7. Val - Validation, 
- competed, 
- in progress, 
- not done
Overview table for the owner and an approver of this feature
1.Description | Land -Ice Add Land Ice Meshes to ACME |
| 2.Owner | Matt Hoffman |
| 3.Created | |
| 4.Equ | |
| 5.Ver | |
| 6.Perf | |
| 7.Val | |
| 8.Approver | |
| 9.Approved Date |
Title: O26_LI Add Land Ice Meshes to ACME
Requirements and Design
ACME Ocean and Ice Group
Date: 2015-9-23
Summary
ACME will be one of the first climate models to include a fully coupled, dynamic ice sheet component. Meshes appropriate for use with the MPAS-LI model, the ice sheet model component in ACME, will need to be added to ACME for: 1) testing purposes, 2) use in configurations where the ice sheet may be dynamically inactive but coupled thermodynamically to the ocean component, and 3) use in configurations with a fully coupled and active ice sheet model component.
Requirements
Requirement: Coarse, uniform resolution meshes for testing
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
Testing of the new ice sheet model in ACME will require inexpensive, coarse, uniform resolution meshes for the land ice model component. This mesh will be used for testing MPAS-LI as an active component in ACME and also for testing initial coupling to the other components of the climate model.
Requirement: Variable resolution meshes for static ice sheet configurations
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
Some ACME simulations may choose to have an inactive ice sheet component. In this case, we can still allow for thermodynamic coupling between the ocean and ice sheet (e.g., so that the ocean can circulate under static ice shelves and exchange heat and fresh water fluxes with the ice sheet). This will require variable resolution meshes with intermediate spatial dimensions.
Requirement: Variable resolution meshes for active ice sheet configurations
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
Accurate simulation of marine ice sheet dynamics - e.g., retreat and advance of ice sheet grounding lines - requires extremely high spatial grid resolution (>=1km) in limited portions of the computational domain covered by the ice sheet. ACME simulations with an active ice sheet component will require variable resolution meshes that allow for this localized high resolution in order to insure accurate simulations of marine ice sheet evolution.
Algorithmic Formulations
Design solution: Uniform and variable resolution SCVT generation
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
Design and Implementation
Implementation: Coarse, uniform resolution Greenland mesh
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
A uniform resolution, 20 km Greenland ice sheet mesh has been designed for the purposes of testing MPAS-LI as an active component in ACME and for testing the coupling between the land and land ice components.
This grid is currently available within ACME (sname="0.9x1.25_gx1v6_gis20" alias="f09_g16_g").
Implementation: Coarse, uniform resolution Antarctic mesh
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
A uniform resolution, 20 km Antarctic ice sheet mesh has been designed for the purposes of testing MPAS-LI as an active component in ACME and for testing the "plumbing" of ice sheet - to - ocean and ice sheet - to - land coupling.
This grid is currently available on an ACME branch (sname="0.9x1.25_gx1v6_ais20" alias="f09_g16_a").
Implementation: Coarse, variable resolution Antarctic mesh
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
A variable resolution, ~15-4 km Antarctic ice sheet mesh has been designed for the purposes of more rigorous testing of MPAS-LI as an active component in AMCE (i.e., allowing for better resolution of localized dynamics and flow features) and for use in configurations where a static, but high-resolution representation of the ice sheet geometry may be needed for thermodynamic coupling to the ocean.
This grid exists and has been tested extensively in MPAS-LI standalone simulations but has not yet been added to ACME.
Implementation: Fine, variable resolution Antarctic mesh
Date last modified: 2015-9-23
Contributors: Matt Hoffman, Stephen Price
A variable resolution, ~20-1 km Antarctic ice sheet mesh will be designed for use in any ACME simulation with an active Antarctic ice sheet component. The mesh generation process is expected to follow similarly from the process of designing and generating the ~15-4 km variable resolution mesh. The necessary density functions for generating the mesh are already in hand.
Planned Verification and Unit Testing
Verification and Unit Testing: short-desciption-of-testing-here
Date last modified:
Contributors: (add your name to this list if it does not appear)
How will XXX be tested? i.e. how will be we know when we have met requirement XXX. Will these unit tests be included in the ongoing going forward?
Planned Validation Testing
Validation Testing: short-desciption-of-testing-here
Date last modified:
Contributors: (add your name to this list if it does not appear)
How will XXX be tested? What observational or other dataset will be used? i.e. how will be we know when we have met requirement XXX. Will these unit tests be included in the ongoing going forward?
Planned Performance Testing
Performance Testing: short-desciption-of-testing-here
Date last modified:
Contributors: (add your name to this list if it does not appear)
How will XXX be tested? i.e. how will be we know when we have met requirement XXX. Will these unit tests be included in the ongoing going forward?
References
Ringler, T., L. Ju, and M. Gunzburger. 2008. A multiresolution method for climate system modeling: application of spherical centroidal Voronoi tessellations. Ocean Dynamics, 58(5), 475-498. link