Difference between revisions of "HowTo:namd"

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= NAMD =
 
= NAMD =
  
This is a short help file on using the parallel electronic-structure code "NWChem" on systems at the Centre for Advanced Computing. This software uses MPI as a message-passing system and is (in principle) able to run on an arbitrary number of processors. Its ability to perform a very broad spectrum of molecular-structure calculations, ranging from CI to ab-initio molecular dynamics, makes it an interesting alternative to the standard electronic structure code Gaussian.  
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This is a quick introduction to the usage of the free but licensed code NAMD2 that is installed on our clusters. It is meant as an initial pointer to more detailed information and a Getting Started primer. It does not replace study of the manual.
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== Features ==
 
== Features ==
  
NWChem is an electronic-structure code that is suitable to perform complex calculations on molecular structure. It was specifically designed to perform well on high-performance parallel computers. The installation on the SunFire cluster of HPCVL employs the MPI message passing package for parallel execution.
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NAMD is a parallel code for molecular dynamics simulation of large biomolecular systems, developed by the Theoretical Biophysics Group ("TBG") in the Beckman Institute of the University of Illinois . It is file-compatible with AMBER, CHARMM, and X-PLOR.
 
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NWChem allows, among others, the following calculations to be performed:
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* Hartree-Fock (e.g. RHF, UHF, ROHF etc.)
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* DFT including spin-orbit DFT, with many exchange and correlation functionals.
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* Complete Active Space SCF (CAS-SCF)
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* Coupled-Cluster (CCSD, CCSD+T, etc.)
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* limited CI (eg, CISD) with perturbative corrections
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* MP2 (2nd-order Mollar-Plesset Perturbation Theory)
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* In general: single-point calculations, geometry optimizations, vibrational analysis.
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* Static one-electron properties, densities, electrostatic potentials.
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* ONIOM model for multi-level calculations on larger systems
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* Relativistic corrections (Douglas-Kroll, Dyall-Dirac, spin-orbit)
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* Ab-initio molecular dynamics (Carr-Parinello)
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* Extended (solid-state) systems DFT
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* Classical force-fields (Molecular Mechanics: AMBER, CHARMM, etc.)
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For a more complete list, see the official NWChem homepage and click on "capabilities".
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== Location of the program and setup ==
 
== Location of the program and setup ==
  
The NWChem program is located in the directory /opt/nwchem/bin. To access it, you have to use the usepackage command
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The binary executable is in /opt/namd on the HPCVL Clusters. The present version of the program is 2.10, and it is available on the Linux platform in its 64 bit version. Therefore, all the relevant executables are in /opt/namd/2.10. Documentation can be found at the main NAMD site and a simple example (Alanin) is in /opt/namd/2.10/example.
<pre>use nwchem</pre>
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which will set you up automatically.
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The setup for NAMD is very simple. It is only necessary type :
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<pre>use namd</pre>
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This will enter the proper directory into your PATH and off you go.
 
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Revision as of 17:46, 14 June 2016

NAMD

This is a quick introduction to the usage of the free but licensed code NAMD2 that is installed on our clusters. It is meant as an initial pointer to more detailed information and a Getting Started primer. It does not replace study of the manual.

Features

NAMD is a parallel code for molecular dynamics simulation of large biomolecular systems, developed by the Theoretical Biophysics Group ("TBG") in the Beckman Institute of the University of Illinois . It is file-compatible with AMBER, CHARMM, and X-PLOR.

Location of the program and setup

The binary executable is in /opt/namd on the HPCVL Clusters. The present version of the program is 2.10, and it is available on the Linux platform in its 64 bit version. Therefore, all the relevant executables are in /opt/namd/2.10. Documentation can be found at the main NAMD site and a simple example (Alanin) is in /opt/namd/2.10/example.

The setup for NAMD is very simple. It is only necessary type :

use namd

This will enter the proper directory into your PATH and off you go.

Running NWChem from a command line

Like other electronic-structure programs, NWChem is run by supplying an input file that defines the system on which to perform a calculation (usually a molecule, or a group of molecules), and the method to use (i.e., the level of calculation, such as "Hartree-Fock", the basis set, and other details of the computation).

The variety of possible calculations is great, and so is the complexity of systems. It is impossible for us here to explain the format that a NWChem input file needs to have. This is explained in the User's Manual which is available online.

Here, we provide a simple sample input file which should be given the file extension .nw.

start h2o

title "H2O, cc-pVDZ basis, SCF optimized geometry"

geometry units au
H       0.0000000000   1.4140780900  -1.1031626600
H       0.0000000000  -1.4140780900  -1.1031626600
O       0.0000000000   0.0000000000  -0.0080100000
end

basis
H library cc-pVDZ
O library cc-pVDZ
end

scf
   thresh 1.0e-8
end

task scf

This extension may be omitted when calling the program. NWChem creates typically a whole array of output files that are documented in the User's Manual. A general log is displayed on the console, and may be saved in a file by redirecting the standard output:

nwchem sample > sample.log

where we assume that your input file is called sample.nw and you want to save the log to a file sample.log.

Note that this is just the basic syntax of the program call. In practise you will use a parallel environment to execute the program (see next section). In fact, executing NWChem by just typing the above line will run it in serial mode.

Parallel Runs

NWChem is inherently parallelized and designed to scale well on a multi-processor machine or a cluster. The underlying parallel system is MPI (Message Passing Interface) which is a commonly available standard that runs on many platforms. Consult our MPI help file and follow some of the links in there if you want to have more information about MPI. Even if you want to use only one processor for your NWChem run (which sometimes is the best solution, particularly for smaller computations), you have to submit the program to a parallel environment. On our clusters, the relevant command is mpirun:

mpirun -np 8 nwchem sample > sample.log

This will run your sample.nw input file on eight processors. Note that you are only allowed to run NWChem this way for small test systems! For any production jobs, you have to submit the task to the scheduler (see next section.).

Submitting (parallel) NWChem jobs

NWChem jobs are to be submitted on the SW (Linux) systems via the GridEngine, which is a load-balancing software. To obtain details, read our GridEngine FAQ . For an NWChem batch job, this means that rather than issuing the command in the previous section directly, you wrap it into a GridEngine batch script.

Here is an example for such a batch script:

#$ -S /bin/bash
#$ -q abaqus.q
#$ -l qname=abaqus.q
#$ -o sample.out
#$ -e STD.err
#$ -M hpcXXXX@localhost
#$ -m be
#$ -V
#$ -cwd
#$ -pe dist.pe 4
mpirun -np $NSLOTS nwchem sample

This script needs to be altered by explicitly replacing the entries that differ in your case. We suggest you use it as a template for all your NWChem runs. For details, consult our Scheduler Help File.

Note that there is no need in this script to redirect the standard output via the > operator. Instead, you define where the output goes to the GridEngine via the "#$ -o" command. In our case, we send it to a file called sample.out.

Email notification is set up through the "#$ -M" line. In the above example you need to replace XXXX by the actual 4 digits in your username, and place a file ".forward" with your email address into your home directory.

In the example we are executing with 4 processes. To choose a different number, alter the "#$ -pe" line in the script. For this example script to work you need to have set up the calling shell through the "use nwchem" command because the above script inherits all the environment settings (due to the "#$ -V" option).

The script is submitted to the GridEngine by typing

qsub batch_file_name

The advantage to submit jobs via a load balancing software is that the software will automatically find the resources required and put the job onto a set of processors that have a low load. This will help executing the job faster. Production jobs on our cluster must be submitted using GridEngine from a login node (sflogin0 or swlogin1), and executed under GE's control on the Linux production nodes without any need for you to log in.

Licensing

NWChem is obtainable free of charge from the Pacific Northwest National Laboratory. To obtain your own copy, go here. NWChem is ditributed under an Open Source Educational Community License. Like with other software, HPCVL requires users who want to use NWChem, to read this agreement, and sign a statement that they have done so and will abide by its terms. You can fax the signed statement to (613) 533-2015 or scan/email it to cac.admin@queensu.ca. You will then be included in a Unix user group that has access to the NWChem executables.

More Information

NWChem is a very complex software package, and requires practice to be used efficiently. We cannot explain it use in any detail here.