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19 projects in result set.
OpenMM
- OpenMM is a toolkit for molecular simulation. It can be used either as a stand-alone application for running simulations, or as a library you call from your own code. It
provides a combination of extreme flexibility (through custom forces and integrators), openness, and high performance (especially on recent GPUs) that make it truly unique among simulation codes.
<b>NEED HELP?</b> Check out the discussion forums under <a href="https://simtk.org/forums/viewforum.php?f=161">Public Forums</a> and the material from our workshops under <a href="https://simtk.org/project/xml/downloads.xml?group_id=161">Downloads</a>.
<b>GET STARTED QUICKLY:</b> Tutorials and sample scripts to run OpenMM are available in the <a href="http://wiki.simtk.org/openmm/VirtualRepository">OpenMM Code Repository</a>.
<b>SOURCE CODE:</b> The source code for OpenMM is available under <a href="https://simtk.org/project/xml/downloads.xml?group_id=161">Downloads</a> and also from the <a href="http://www.github.com/SimTk/openmm">Github Source Code Repository</a>.
<b>BENCHMARKS:</b> A collection of <a href="http://wiki.simtk.org/openmm/Benchmarks">benchmarks</a> is available to show the performance of OpenMM simulating a variety of molecular systems.
<b>CITING OPENMM:</b> Any work that uses OpenMM should cite the papers listed on the <a href="https://simtk.org/project/xml/publications.xml/?group_id=161">Publications</a> page. | |
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Registered: 2006-11-16 18:27 |
ProtoMol
- ProtoMol is an object-oriented, component based, framework for molecular dynamics (MD) simulations. The framework supports the CHARMM 19 and 28a2 force fields and is able to process PDB, PSF, XYZ and DCD trajectory files. It is designed for high flexibility, easy extendibility and maintenance, and high performance demands, including parallelization. The technique of multiple time-stepping is used to improve long-term efficiency. The use of fast electrostatic force evaluation algorithms like Ewald, particle Mesh Ewald (PME), and Multigrid (MG) summation further enhances performance. Longer time steps are possible using MOLLY, Langevin Molly and Hybrid Monte Carlo, Nose-Hoover, and Langevin integrators.
<b>Key Features of ProtoMol 3.0 (available Summer 2009):</b>
1) Interface to OpenMM, an MD library with NVIDIA and ATI general purpose GPU support. OpenMM supports AMBER force fields and Generalized-Born implicit solvent.
2)Python bindings offered as MDLab, which allow for prototyping of high level sampling protocols, new integrators, and new force calculations in Python.
3) Coarse grained normal mode analysis (CNMA), which provides a scalable O(N9/5) time and O(N3/2) memory diagonalization. CNMA approximates low frequency modes very well.
4) Normal Mode Langevin (NML) dynamics, which uses CNMA to periodically compute low frequency bases for propagation of dynamics, while fast modes are minimized to their equilibrium position. NML allows timesteps of 100 fs and more for even small proteins (> 30 residues) with real speedups that are about a third of the timestep used.
5) Full checkpointing support, which simplifies use in distributed computing platforms such as Condor or Folding@Home. | |
Activity Percentile: 70.99 Registered: 2009-05-28 17:47 |
Simbody: Multibody Physics API
- This project is a SimTK toolset providing general multibody dynamics capability, that is, the ability to solve Newton's 2nd law F=ma in any set of generalized coordinates subject to arbitrary constraints. (That's Isaac himself in the oval.) Simbody is provided as an open source, object-oriented C++ API and delivers high-performance, accuracy-controlled science/engineering-quality results.
Simbody uses an advanced Featherstone-style formulation of rigid body mechanics to provide results in Order(<em>n</em>) time for any set of <em>n</em> generalized coordinates. This can be used for internal coordinate modeling of molecules, or for coarse-grained models based on larger chunks. It is also useful for large-scale mechanical models, such as neuromuscular models of human gait, robotics, avatars, and animation. Simbody can also be used in real time interactive applications for biosimulation as well as for virtual worlds and games.
This toolset was developed originally by Michael Sherman at the Simbios Center at Stanford, with major contributions from Peter Eastman and others. Simbody descends directly from the public domain NIH Internal Variable Dynamics Module (IVM) facility for molecular dynamics developed and kindly provided by Charles Schwieters. IVM is in turn based on the spatial operator algebra of Rodriguez and Jain from NASA's Jet Propulsion Laboratory (JPL), and Simbody has adopted that formulation.
<b>SOURCE CODE:</b> Simbody is distributed in source form. The source code is maintained at <a href="https://www.github.com/simbody">GitHub</a>. You can get a zip of the latest stable release <a href="https://github.com/simbody/simbody/releases">here</a>, then build it on your Windows, Mac OSX, or Linux machine (you will need CMake and a compiler).
You can also clone the git repository and build the latest development version <a href="https://github.com/simbody/simbody">here</a>; the repository URL is https://github.com/simbody/simbody.git. If you would like to contribute bug fixes, new code, documentation, examples, etc. to Simbody (and we hope you will!), please fork the repository on GitHub and send pull requests.
If you are new to git, you may want to start with GitHub's <a href="https://help.github.com/categories/54/articles">Bootcamp tutorial</a>. | |
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Registered: 2005-07-26 19:52 |
MSMBuilder
- MSMBuilder is an open source software package for automating the construction and analysis of Markov state models (MSMs). It is primarily written in the python programming language with C extensions for the most time consuming routines.
MSMs are a powerful means of modeling the structure and dynamics of molecular systems, like proteins. An MSM is essentially a map of the conformational space a molecule explores. Such models consist of a set of states and a matrix of transition probabilities (or, equivalently, transition rates) between each pair of states. Intuitively, the states in an MSM can be thought of as corresponding to local minima in the free energy landscape that ultimately determines a molecule’s structure and dynamics.
MSMBuilder includes tools for
- Constructing an MSM from a set of computer simulations (typically molecular dynamics simulations in standard formats like xtc, dcd, and pdb)
- Validating statistical properties of MSMs
- Mimicking various experimental protocols to allow a quantitative comparison with experiments
- Driving efficient simulations via adaptive sampling (which decides where new simulations should be run to minimize statistical uncertainty in a model)
<p style="font-size:20px">For more information, including the latest releases, see our website at</p><p style="font-size:20px; text-align:center; font-weight:600;"><a href="http://msmbuilder.org">MSMBuilder.org</a></p> | |
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Registered: 2008-11-26 04:53 |
Lepton Mathematical Expression Parser
- Lepton ("lightweight expression parser") is a small C++ library for parsing, evaluating, differentiating, and analyzing mathematical expressions. | |
Activity Percentile: 11.07 Registered: 2009-11-04 01:56 |
SimTK Core Toolset (obsolete project)
- Prior to June, 2011 this project was used to distribute the Simbios-developed Simbody and Molmodel packages in the SimTK biosimulation toolkit. These are now distributed separately from the Simbody and Molmodel projects (https://simtk.org/home/simbody, https://simtk.org/home/molmodel). Please use those projects instead of this one.
The other major component of SimTK is the GPU-accelerated molecular dynamics package OpenMM, see https://simtk.org/home/openmm if you are interested.
<b>The text below refers to the pre-June, 2011 packaging and has been superseded as described above.</b>
<b><i>SimTK Core subprojects</i></b> This SimTK Core project collects together all the binaries needed for the various SimTK Core subprojects. These include Simbody, Molmodel, Simmath (including Ipopt), Simmatrix, CPodes, SimTKcommon, and Lapack. See the individual projects for descriptions.
<b><i>SimTK overview</i></b>
SimTK brings together in a robust, convenient, open source form the collection of highly-specialized technologies necessary to building successful physics-based simulations of biological structures. These include: strict adherence to an important set of abstractions and guiding principles, robust, high-performance numerical methods, support for developing and sharing physics-based models, and careful software engineering.
<b><i>Accessible High Performance Computing</i></b><br/>
We believe that a primary concern of simulation scientists is performance, that is, speed of computation. We seek to build valid, approximate models using classical physics in order to achieve reasonable run times for our computational studies, so that we can hope to learn something interesting before retirement. In the choice of SimTK technologies, we are focused on achieving the best possible performance on hardware that most researchers actually have. In today's practice, that means commodity multiprocessors and small clusters.
The difference in performance between the best methods and the do-it-yourself techniques most people use can be astounding—easily an order of magnitude or more. The growing set of SimTK Core libraries seeks to provide the best implementation of the best-known methods for widely used computations such as:
Linear algebra, numerical integration and Monte Carlo sampling, multibody (internal coordinate) dynamics, molecular force field evaluation, nonlinear root finding and optimization. All SimTK Core software is in the form of C++ APIs, is thread-safe, and quietly exploits multiple CPUs when they are present.
The resulting pre-built binaries are available for download and immediate use.
<b><i>Citation:</i></b> Any work that uses SimTK Core (including Simbody) should cite the following paper: Jeanette P. Schmidt, Scott L. Delp, Michael A. Sherman, Charles A. Taylor,Vijay S. Pande, Russ B. Altman, "The Simbios National Center: SystemsBiology in Motion", Proceedings of the IEEE, special issue on Computational System Biology. Volume 96, Issue 8:1266 - 1280. (2008) | |
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Registered: 2006-04-04 20:03 |
ForceBalance : Systematic Force Field Optimization
- ForceBalance is free software for force field optimization.
It facilitates the development of more accurate force fields using a systematic and reproducible procedure.
ForceBalance is highly versatile and can optimize nearly any set of parameters using experimental measurements and/or ab initio calculations as reference data.
<b>SOURCE CODE:</b> For the newest features, visit the GitHub source code repository at https://github.com/leeping/forcebalance.
The SVN repository on the left frame is an outdated archive.
<b>RELEASES:</b> Stable versions of the code updated once every few months. Click "Releases" on the left frame for the most recent release and notes.
<b>CONTACT:</b> Please contact me (Lee-Ping, right frame) if you have questions or comments! | |
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Registered: 2011-12-20 17:04 |
Thermodynamics and Kinetics of Biomolecular Folding
- SimTK RNA_Fold project aims to understand the accurate folding pathways of RNA molecules. Free energy landscape of RNA folding will be studied for all atom model or physical based coarse graining model. Replica exchange Molecular Dynamics, simulated tempering and other sampling methods will be used to enhance sampling. Folding@Home distributed computing will be used due to its big computing power. | |
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Activity Percentile: 0.00 Registered: 2006-08-29 18:41 |
Clustering Algorithms for Massively Parallel Architectures Including GPU Nodes
- The CAMPAIGN project’s goals are to modularize and parallelize clustering algorithms and explore new clustering approaches, with special concentration on running on GPUs. | |
Activity Percentile: 0.00 Registered: 2009-10-26 21:16 |
C++ and Python code, distributed computing and OpenMM interfaces for simulations
- please cite: "Interplay of Protein and DNA Structure Revealed in Simulations of the lac Operon" (PLOS One 2013)
for any code related to protein-DNA modeling and
"Free Energy Monte Carlo Simulations on a Distributed Network" (Lecture Notes in Computer Science Journal for PARA 2010)
http://link.springer.com/chapter/10.1007%2F978-3-642-28145-7_1
for parallel client-server code, users of additional code should cite this web site. Code is provided as-is with no warranty and examples are provided to illustrate the usage of these modeling techniques with some sample systems. Code is the intellectual property of Luke Czapla, developer and biophysicist. Examples are provided in C/C++ and Python. | |
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Activity Percentile: 0.00 Registered: 2014-02-01 22:32 |
Breeder : genetic algorithm based protein-protein interface optimizer
- This algorithm submits many MMB equilibration and FoldX energy evaluation jobs to a cluster and finds sequences with improved binding energy. | |
Activity Percentile: 0.00 Registered: 2013-04-30 12:06 |
HTMD - High Throughput Molecular Dynamics
- In a single script, it is possible to plan an entire computational experiment, from manipulating PDBs, building, executing and analyzing simulations, computing Markov state models, kinetic rates, affinities and pathways.
See more information on <a href="https://www.htmd.org/">https://www.htmd.org</a>.
HTMD Forum: <a href="https://forum.htmd.org/">https://forum.htmd.org</a>
We are also on Github: <a href="https://github.com/Acellera/htmd">https://github.com/Acellera/htmd</a>
Report issues on: <a href="https://github.com/Acellera/htmd/issues">https://github.com/Acellera/htmd/issues</a> | |
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Registered: 2016-05-13 07:45 |
Open MM and Zephyr applications to XBOX360 platform.
- This project is intended to use the OpenMM and Zephyr source code for compilation upon the XBOX 360 platforms. An executable with the functionality of Zephyr is desired. | |
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Activity Percentile: 0.00 Registered: 2009-12-25 17:02 |
Computational Analysis of Kinase Selectivity using Structural Knowledge
- Here, we present a knowledge-based approach to profile kinase selectivity based on the similarity between drug binding microenvironments. To allow large-scale kinase site similarity profiling, we have created a kinome structure database consisting of 5000 inhibitor-binding pockets from 187 unique human kinase crystal structures. | |
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Registered: 2017-04-18 20:03 |
KGS: Sampling and Characterizing Protein and RNA conformational landscapes
- The Kino-Geometric Sampling (KGS) software suite uses advanced, robotics-inspired algorithms to rapidly explore the conformational landscape of folded proteins, RNA, and their complexes. Combined with powerful statistical techniques, it structurally characterizes collective motions and excited substates from sparse, spatiotemporally averaged data. | |
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Activity Percentile: 0.00 Registered: 2015-12-11 21:41 |
Molmodel: SimTK molecular modeling API
- Molmodel is a programmer’s toolkit for building reduced-coordinate, yet still all-atom, models of large biopolymers such as proteins, RNA, and DNA. You control the allowed mobility. By default, Molmodel builds torsion-coordinate models in which bond stretch and bend angles are rigid while bond torsion angles are mobile. But you can rigidify or free any subsets of the atoms, such as the rigid benzene ring shown here.
Molmodel is a C++ API for biochemist-friendly molecular modeling that extends the Simbody API to simplify construction of high-performance articulated models of molecules. All of the Simbody API is available when using Molmodel and Simbody must be installed and functioning in order to use Molmodel. See https://simtk.org/home/simbody for more information. Read the Simbody User’s Guide for background, installation instructions, and examples.
Molmodel can produce models with dramatically fewer degrees of freedom than a typical molecular model, yet the reduced set of coordinates is still a fully nonlinear basis for molecular motions of any size. Structural searches and optimizations benefit from a much reduced search space, Monte Carlo moves can achieve much higher acceptance rates, and dynamics can proceed with much larger step sizes due to the lower natural frequencies produced by larger moving bodies. Because all the atoms are still present, conventional force fields and implicit solvent models can be used for energy and force computations, and Molmodel can use OpenMM (https://simtk.org/home/openmm) to accelerate those calculations. Alternatively, Molmodel is flexible enough to allow you to design your own force fields. Physics-based, knowledge-based, and special-purpose potentials can be designed and incorporated into your Molmodel model.
While reduced coordinate models have been used succesfully for a variety of purposes (they are ubiquitous in NMR structure refinement, for example), research is needed to determine the best way to model a given molecular system for the particular study at hand. Both the physical properties of a molecular system of interest, and the particular investigation being performed will influence the best choice of model. The point of Molmodel is to enable you or users of your software to perform those studies by providing making it easy to create molecular models with mobility only where you choose to allow it, and then to easily revise those choices.
Molmodel, Simbody, and OpenMM are components of the open source biosimulation toolkit SimTK, developed and supported by the NIH-funded Center for Physics-Based Simulation of Biological Structures at Stanford (http://simbios.stanford.edu). Molmodel was developed originally for SimTK by Christopher Bruns and Michael Sherman, with major contributions from Peter Eastman and Samuel Flores.
<b>NOTE:</b> Prior to the 2.2 release, binaries of Molmodel were bundled with other SimTK Core modules. Those can still be found in the Downloads section of the SimTKcore project, at http://simtk.org/home/simtkcore. | |
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Registered: 2007-03-01 17:33 |
WebFEATURE
- FEATURE is an automated tool that examines biological structures and produces useful representations of the key biophysical and biochemical features of these structures that are critical for understanding function. WebFEATURE provides a web-based interface to FEATURE and extends FEATURE with visualization tools to explore functional site models and functional site predictions. | |
Activity Percentile: 0.00 Registered: 2012-01-09 20:54 |
MoSART: NMR-based Biomolecular Structure Computation
- MoSART (Molecular Structure Analysis and Refinement Tool) is designed for computing biomolecular structure from NMR data. The goal of the project is to create an easily extensible package that will broaden the community of developers of new approaches to computation of biomolecular structure from NMR data. A key feature is support for low-resolution (two particles per residue for proteins, 3/4 particles per residue for nucleic acids) force fields, useful when geometrical restraints are sparse. These facilitate determination of the overall fold during early stages of an NMR investigation, or starting points for hierarchical structure determination. Future plans include additional support for low resolution geometrical constraints derived from NMR and chemical footprinting to support membrane protein structure determination. | |
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Activity Percentile: 0.00 Registered: 2006-05-03 22:11 |
PySimTK: SimTK core multibody dynamics tool kit in python
- This project creates an easier to use python API for the SimTK core multibody mechanics simulation tool kit. | |
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Registered: 2009-07-29 17:59 |