Difference between revisions of "AMBER"

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==Required Modules==
 
==Required Modules==
 
===Serial===
 
===Serial===
* intel/2016.0.109
+
* intel/2018.1.163
 
* amber
 
* amber
  
 
Example:
 
Example:
  module load intel/2016.0.109 amber
+
  module load intel/2018.1.163 amber
  
 
===Parallel (MPI)===
 
===Parallel (MPI)===
* intel/2016.0.109
+
* intel/2018.1.163
* openmpi/1.10.2
+
* openmpi/3.0.0
 
* amber
 
* amber
  
 
Example:
 
Example:
  module load intel/2016.0.109 openmpi amber
+
  module load intel/2018.1.163 openmpi/3.0.0 amber
  
 
===GPU (Serial)===
 
===GPU (Serial)===
* intel/2016.0.109
+
* cuda/9.1.85
 +
* intel/2017.4.056
 
* amber/16-cuda
 
* amber/16-cuda
  
 
Example:
 
Example:
  module load intel/2016.0.109 amber/16-cuda
+
  module load cuda/9.1.85 intel/2017.4.056 amber/16-cuda
  
 
===GPU (Parallel/MPI)===
 
===GPU (Parallel/MPI)===
* intel/2016.0.109
+
* cuda/9.1.85
* openmpi/1.10.2
+
* intel/2017.4.056
 +
* openmpi/3.0.0
 
* amber/16-cuda
 
* amber/16-cuda
  
 
Example:
 
Example:
  module load intel/2016.0.109 openmpi amber/16-cuda
+
  module load cuda/9.1.85 intel/2017.4.056 openmpi/3.0.0 amber/16-cuda
  
 
==System Variables==
 
==System Variables==

Revision as of 19:22, 25 May 2018

Description

Amber website  

Amber refers to two things: a set of molecular mechanical force fields for the simulation of biomolecules (which are in the public domain, and are used in a variety of simulation programs); and a package of molecular simulation programs which includes source code and demos.

A good general overview of the Amber codes can be found in: D.A. Case, T.E. Cheatham, III, T. Darden, H. Gohlke, R. Luo, K.M. Merz, Jr., A. Onufriev, C. Simmerling, B. Wang and R. Woods. The Amber biomolecular simulation programs. J. Computat. Chem. 26, 1668-1688 (2005).

An overview of the Amber protein force fields, and how they were developed, can be found in: J.W. Ponder and D.A. Case. Force fields for protein simulations. Adv. Prot. Chem. 66, 27-85 (2003). Similar information for nucleic acids is given by T.E. Cheatham, III and M.A. Young. Molecular dynamics simulation of nucleic acids: Successes, limitations and promise. Biopolymers 56, 232-256 (2001).

Version

The default version is Amber 16.

Due to its license policy, users who wish to use it will need to obtain the permission from Dr. Adrian Roiberg and submit a help request at: http://support.rc.ufl.edu. You will then be added to "amber" group (as your secondary group) for accessing Amber 16.

Required Modules

Serial

  • intel/2018.1.163
  • amber

Example:

module load intel/2018.1.163 amber

Parallel (MPI)

  • intel/2018.1.163
  • openmpi/3.0.0
  • amber

Example:

module load intel/2018.1.163 openmpi/3.0.0 amber

GPU (Serial)

  • cuda/9.1.85
  • intel/2017.4.056
  • amber/16-cuda

Example:

module load cuda/9.1.85 intel/2017.4.056 amber/16-cuda

GPU (Parallel/MPI)

  • cuda/9.1.85
  • intel/2017.4.056
  • openmpi/3.0.0
  • amber/16-cuda

Example:

module load cuda/9.1.85 intel/2017.4.056 openmpi/3.0.0 amber/16-cuda

System Variables

  • AMBERHOME
  • HPC_{{#uppercase:Amber}}_DIR - installation directory
  • HPC_{{#uppercase:Amber}}_BIN - executable program directory
  • HPC_{{#uppercase:Amber}}_LIB - library directory
  • HPC_{{#uppercase:Amber}}_INC - include file directory


Job Script Examples

See the AMBER_Job_Sample_Scripts page for Amber Job script examples.



Citation

Serial Version

If you publish research that uses Amber you have to cite it as follows:
D.A. Case, T.A. Darden, T.E. Cheatham, III, C.L. Simmerling, J. Wang, R.E. Duke, R. Luo, R.C. Walker, W. Zhang, K.M. Merz, B. Roberts, S. Hayik, A. Roitberg, G. Seabra, J. Swails, A.W. Goetz, I. Kolossvai, K.F. Wong, F. Paesani, J. Vanicek, R.M. Wolf, J. Liu, X. Wu, S.R. Brozell, T. Steinbrecher, H. Gohlke, Q. Cai, X. Ye, J. Wang, M.-J. Hsieh, G. Cui, D.R. Roe, D.H. Mathews, M.G. Seetin, R. Salomon-Ferrer, C. Sagui, V. Babin, T. Luchko, S. Gusarov, A. Kovalenko, and P.A. Kollman (2012), AMBER 12, University of California, San Francisco.

GPU Version

If you make use of any of this GPU support in your work please use the following citations:

Andreas W. Goetz; Mark J. Williamson; Dong Xu; Duncan Poole; Scott Le Grand; & Ross C. Walker* "Routine microsecond molecular dynamics simulations with AMBER - Part I: Generalized Born", J. Chem. Theory Comput., 2012, 8 (5), pp 1542-1555 , DOI: 10.1021/ct200909j

D.A. Case, T.A. Darden, T.E. Cheatham, III, C.L. Simmerling, J. Wang, R.E. Duke, R. Luo, R.C. Walker, W. Zhang, K.M. Merz, B. Roberts, S. Hayik, A. Roitberg, G. Seabra, J. Swails, A.W. Goetz, I. Kolossvai, K.F. Wong, F. Paesani, J. Vanicek, R.M. Wolf, J. Liu, X. Wu, S.R. Brozell, T. Steinbrecher, H. Gohlke, Q. Cai, X. Ye, J. Wang, M.-J. Hsieh, G. Cui, D.R. Roe, D.H. Mathews, M.G. Seetin, R. Salomon-Ferrer, C. Sagui, V. Babin, T. Luchko, S. Gusarov, A. Kovalenko, and P.A. Kollman (2012), AMBER 12, University of California, San Francisco.