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MIcro Simulation Tool
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Copyright (C) 2013-2018 Jacob Barhak Copyright (C) 2009-2012 The Regents of the University of Michigan License GPL 3 - See full details below CONTENTS: 1. INTRODUCTION 2. INSTALLATION 3. HOW TO USE THE SOFTWARE 4. FILES 5. KNOWN BUGS AND FEATURES 6. VERSION HISTORY 7. CONTACT INFORMATION AND SUPPORT 8. ACKNOWLEDGEMENTS 9. LICENSE 1. INTRODUCTION: This software supports modeling and Monte-Carlo micro-simulation of parallel state transition processes. It is initially intended to allow modeling of chronic diseases, yet the software is general and may accommodate other models. The GitHub project web site is: https://github.com/Jacob-Barhak/MIST The SimTk project web site is: https://simtk.org/home/mist For a video introduction and additional information, please visit the following links: http://www.youtube.com/watch?v=AD896WakR94 For additional information and an example of use, see: https://www.youtube.com/watch?v=vyvxiljc5vA 2. INSTALLATION: The system can be installed in several fashions in different platforms. There are even expert installations for High Performance Computing (HPC) for advanced and expert users. For novice users it is recommended that you use Windows since it is the simplest to install and the Graphic User Interface (GUI) was tested there. For HPC features you will need to use a Linux installation. Simple Installation Instructions: 1. Download and Install Anaconda with python 2.7 version from https://www.anaconda.com/download/ 2. Install MIST into your anaconda directory by typing the following text in a command terminal: conda install mist -c jacob-barhak This installation should work on Windows and on Ubuntu Linux. Your working directory in this case would be MIST under the anaconda directory you chose during anaconda installation. Alternative Longer Expert Installation Instructions: 1. Download and Install Anaconda with python 2.7 from https://www.anaconda.com/download/ 2. Install the Inspyred library by typing the following text in a command terminal: pip install inspyred . For additional details see: https://pythonhosted.org/inspyred/overview.html#installation 3. Install WxPython library by typing the following text in a command terminal: conda install wxpython . This library is needed for GUI only. For additional details and other ways to install WxPython see: http://www.wxpython.org/download.php#stable 4. Download the file MIST-master.zip from github by typing the following URL in a web browser: https://github.com/Jacob-Barhak/MIST/archive/master.zip 5. Unzip the file MIST-master.zip in a directory of your choice. This will be your working directory. To Test the Above Installations: 1. Open a command line prompt/terminal and change the directory to your working directory using the command cd <working directory> - with a simple installation your working directory would be MIST subdirectory under your anaconda installation directory - for example c:\Anaconda\MIST on windows, yet this can be changed by the user, so be attentive. 2. From the command line in your working directory write the following text: python TestCode.py . It will test the data definitions and algorithms and should take a good portion of an hour - about half an hour on a descent machine. If you got an all caps "OK" at the end, then you installed the python environment correctly. 3. From the command line in your working directory write the following text: python MISTGUI.py . You should see the Graphic User Interface. If the main window shows up, then the WxPython part is installed correctly. You can try to file->load the file Testing.zip in the InData sub directory to see the examples. If you are an expert you can install and setup MIST to work in HPC environment. These expert installations may require professional support. Please feel free to use the contact information below for assistance. To run MIST Over the Cloud a More Complicated Setup is Needed: 1. Install StarCluster http://star.mit.edu/cluster/docs/latest/installation.html 2. Follow the instructions on http://continuum.io/blog/starcluster-anaconda 3. If you have not done so already follow the Simple Installation Instructions from above on your machine 4. Install the nfsshare.py plugin by copying the file https://github.com/scrappythekangaroo/StarClusterPlugins/commit/775500618279f2fd83e2b7365b5c86cf07e11975 to the StarCluster plugins directory. 5. Change the config file to include all plugins of interest and add plugin parameters. At the end of setup the "Configuring StarCluster Plugins" section in the config file should have the following lines: [plugin anaconda_plugin] SETUP_CLASS = anaconda_plugin.ConfigAnaconda [plugin nfsshare] SETUP_CLASS = nfsshare.NFSSharePlugin SERVER_PATH = /mnt/vol0 CLIENT_PATH = /mnt/vol0 EXPORT_NFS_SETTINGS = sync,no_root_squash,no_subtree_check,rw MOUNT_NFS_SETTINGS = vers=3,user,rw,exec,noauto [plugin webapp-packages-installer] setup_class = starcluster.plugins.pypkginstaller.PyPkgInstaller packages = inspyred Also, the plugins should be declared under the section that has your cluster name using the following line: PLUGINS = anaconda_plugin , nfsshare , webapp-packages-installer For additional information see the following links: http://continuum.io/blog/starcluster-anaconda http://star.mit.edu/cluster/docs/latest/plugins/pypkginstaller.html https://github.com/scrappythekangaroo/StarClusterPlugins/commit/775500618279f2fd83e2b7365b5c86cf07e11975 6.Use the StarCluster put command to transfer MIST to the /mnt/vol0 directory on the cluster It is also possible to run MIST simulations in Multi-core environment using Sun Grid Engine. If you wish to install Sun-Grid-Engine on a single machine for testing purposes: 1. Follow the instructions on http://scidom.wordpress.com/2012/01/18/sge-on-single-pc/ 2. Follow the Quick Installation for Linux from above 3. HOW TO USE THE SOFTWARE: Open a command window and cd to the working directory created during installation then write python MISTGUI.py. The main form titled as 'MIcroSimulation Tool (MIST)' will open. In some systems it is enough to double-click MISTGUI.py to launch the system. The system includes a help system and an example file to aid in learning how to use it. To get started, select help menu in the main form and then select the help sub-option. This will bring up the getting started help page. You may wish to start learning the system by loading the example file Testing.zip from within the system and exploring it. The examples there are described in details in the file SimulationExamples.pdf 4. FILES: The software contains the following files: ~~~~~~~~~~~~~~ Data Definitions ~~~~~~~~~~~~~~ The following files handle the data: DataDef.py : Defines the data structures of the system. TestCode.py : A test script that validates the simulation system integrity by running predetermined input examples. ConvertDataToCode.py : A utility that converts zip file generated by the system to a python script. MultiRunCombinedReport.py : A utility that allows combining results from several runs of the same model and population set into a single report. The use of this utility allows running multiple simulations in parallel and combining their results. MultiRunSimulation.py : A utility that allows running the same simulation multiple times outside the GUI. Useful for parallel processing on multiple computers. It can be used well with MultiRunSimulationStatisticsAsCSV.py to generate a summary statistics for repetitions. MultiRunSimulationStatisticsAsCSV.py : A utility that generates CSV summary reports from several runs of the same project. Combines well with MultiRunSimulation.py that generates input files for this CSV report. The output consists of mean,STD,median,min,max of report columns with regard to different simulation results. MultiRunExportResultsAsCSV.py : A utility that generates a CSV file containing the data from a set of result files. AssembleReportCSV.py : A utility that assembles a CSV file from multiple CSV files generated by MultiRunExportResultsAsCSV.py CreatePlotsFromCSV.py : A utility that constructs plots in a PDF file. The plot data is collected from a CSV file assembled by AssembleReportCSV.py ~~~~~~~~~~~~~~ Graphic User Interface ~~~~~~~~~~~~~~ CDMLib.py : The main library defining the system GUI MISTGUI.py : The main file that starts the application GUI with the main form Parameters.py : The parameters form in the GUI PopulationSets.py : The population set form in the GUI PopulationData.py : The population data form in the GUI used by population set Project.py : The project form in the GUI ReportViewer.py : The report viewer form in the GUI and called by many forms ResultViewer.py : The result viewer form in the GUI used by the Project form States.py : The states form in the GUI StudyModels.py : The model form in the GUI Transitions.py : The Transition form in the GUI used by the Study/Models form Wizard.py : The Cost/QoL Wizard form in the GUI HelpInterface.py : Defined the help interface between forms and html files in the documentation ~~~~~~~~~~~~~~ Supporting Files ~~~~~~~~~~~~~~ The following files and directories are provided: README.txt : This file, that you are now reading License.txt : The GPL license text DocSrc.texi : The Texinfo source file used to generate the html help files using the command makeinfo --html DocSrc.texi Documentation : A directory that holds all the html help files ImagePreperation.odp : A presentation file that is used to generate images for the html help files using the save as jpg. CopyImages.bat : A batch file to copy documentation images to their proper location to match the html files that form the help system Temp : A directory containing temporary data generated while the system is running - the system recreates it if deleted. InData : A directory for input data files - initially holding example file Testing.zip InData/Testing.zip : A data file generated by TestCode.py and contains simulation examples. The examples correspond to those described in SimulationExamples.pdf. InstConda : A directory containing conda build files InstConda/bld.bat : Windows build file for conda InstConda/build.sh : Bash build file for conda InstConda/meta.yaml: Build information meta file for conda SimulationExamples.pdf : A document describing the examples in Testing.zip that are used to test the simulation system. It also contains calculations of the expected outcomes and provide a description of tests carried out in TestCode.py. SimulationExamples.doc : The original word version from which SimulationExamples.pdf was created. TestingResults.mdb : A Microsoft Access Database used to test the report mathematics performing the same calculations as the system and outputs files that can be loaded into TestCode.txt. The file contains visual basic code that generates csv files from InputExample.py results. These csv files can then be converted back to code that is merged into InputExample.py as testing code. ClusterRun.py : A Python script for running multiple simulations with variation overrides on a cluster with some enhancements such as creating plots. This file should be modified before use to fit the cluster it is running on - otherwise it will probably not work. CodeFromDocAndSpreadsheet.py : A python script that converts rule text from a word document and CSV file from a spreadsheet with populations into code and a model file. This script was created to handle a specific format used with the Michigan model documentation. This file relies on a very specific format of documents and remains undocumented and should be treated as an example for programmers that want to extend the system. 5. KNOWN BUGS AND FEATURES: This version contains only simulation capabilities. Note that there are some versions with more advanced capabilities that are not publicly released. The examples provided with the system are used for testing the system. Running the TestCode.py script will test that the simulation system is working properly. Running this file will also create the file Testing.zip that is the data file the system can load and tests the simulation results. The file SimulationExamples.pdf analyses these examples and allows results comparison that is performed when TestCode.py is run. To run this in verbose mode from the command line, change the working directory to the installation directory and type nosetests -s In addition to the above test script, below is a list of known bugs and issues uncovered during testing that were not yet addressed at the time of this release: The GUI was tested on Windows environment and on Linux Ubuntu 12.04. Computations were tested on both Windows and Linux environments through the TestCode.py script. Cloud computations were also tested. Current issue list can be found on Github issues: https://github.com/Jacob-Barhak/MIST/issues Legacy Known Bugs: J0100: WXPYTHON ISSUES ON UBUNTU 12.4 This issue exists only if trying to build WxPython from source code and not a MIST issue, yet reported here anyway. Fortunately, with conda, there is no need to do this any longer. This issue is resolved on Ubuntu 12.04, Ubuntu 14.04, Fedora 21 Linux distributions. At the time of MIST 0.90.0.0 release WxPython does not work on Ubuntu 12.4 since there is a dependency GLIBC_2.15 that is not installed. This may prohibit users from using MIST GUI on the stable release of Ubuntu. The following command installs WxPython on those systems without need to build: conda install wxpython -c asmeurer Note that other Linux systems have not been tested therefore this issue is not removed from the list. Otherwise the issue has been resolved, especially if using the simple conda installation for MIST. Comments/Suggestions & Feature Requests: R0021: LIST OF COEFFICIENTS FOR COST WIZARD When using the Cost/QoL wizard, the drop down list for coefficients lists states that do not belong to the project. Selecting these states is allowed, but when you try to run the simulation, you get an error that the state could not be found. The error should come while using/closing the Cost Wizard, or the non-included states should not be listed at all. INSTRUCTIONS TO REPRODUCE 1. Use Cost Wizard on a project such as example 1 2. Add a state that isn't in the selected project, such as Angina for example 1 3. Run Simulation J0007: IMPROVE MESSAGES TO USER MECHANISM FOR SIMULATION LOG Currently a simulation shows messages to the user in a command box behind the windows while preparing or running a simulation. In the future, it would be nice to have a window that holds a log for user messages, possibly with different colors for different levels of information that the user can conveniently browse and study. J0011: USER CAN OVERRIDE POPULATION REPAIR AND ADVERSELY AFFECT SIMULATION The user can create a population with the main process not defined and a state in that sub-process set. If the system option RepairPopulation is set to False, the simulation will end after one time step since the main process will reset all states afterwards. This is unreasonable behavior that should be banned. J0016: CONSIDER ADDING STARTED AND EXITED STATE INDICATORS Considered adding state indicators _Exited , _Started that will contain additional information regarding a state. This will allow assessing which transition was used and if an individual moved from a certain state. Also consider adding special state indicators such as _Duration to keep the time a user was in the state. J0020: ALLOW BOTTOM UP CASCADING CHANGES THROUGH SPECIAL GUI Currently, if a parameter was user by any entity in the system, it cannot be changed. There are work-around solutions that allow creation of copies. However, if multiple entities are involved, many copies of many entities should be created. This increases the chance of human error and it is just cumbersome. Moreover, the problem is not only with parameters, is it with any entity that is used by another entity. The locks are in place for a reason and the system provides a data to code tool that allows recreating a data base from scratch where this change is present. However, it is still not easy for a user who just wants to go back and make a simple change in a parameter value/formula or even just a note for a state. Adding a special version of the GUI that will allow making this change through forms just for the purpose of reconstructing a database will be helpful. J0030: It is impossible to cancel simulation of population generation from GUI While running the simulation from GUI in Windows, there is no cancel button that can be pressed to stop the simulation. In some cases, this is desirable and it would be a nice to have feature. There is a cancel button in the Linux version since version 0.78.0.0. 6. VERSION HISTORY: MIST Version (0,92,5,0,'MIST') - 1-May-2018: - Additional fix of meta.yaml to uplaod to Github and version bump MIST Version (0,92,4,0,'MIST') - 1-May-2018: - Fix meta.yaml to allow conda build MIST Version (0,92,3,0,'MIST') - 1-May-2018: - Fix to the conda build to get the proper version of wxpython MIST Version (0,94,5,0,'MIST') - 18-Apr-2018 - Not Made Public: - Minor Fix to Dask run MIST Version (0,94,4,0,'MIST') - 14-Apr-2018 - Not Made Public: - Added test for dask parallel execution of multiple simulations MIST Version (0,94,3,0,'MIST') - 9-Apr-2018 - Not Made Public: - Port back fixes from versions 0,92,1,0 and 0,92,2,0 - Added multiprocess execution option using dask - Minor documentation changes, copyright updates, and spelling fixes MIST Version (0,92,2,0,'MIST') - 14-Feb-2018: - This version includes back fixes and not the most advanced version of MIST - This version includes a fix to the conda build on windows MIST Version (0,92,1,0,'MIST') - 13-Feb-2018: - This version includes back fixes and not the most advanced version of MIST - Fix plot engine to match newer MatPlotLib version - Improved Behavior of MultiRunSimulation.py that conserves disk space and works better with MultiRunSimulationStatisticsAsCSV - Minor GUI Fixes - Minor documentation fixes MIST Version (0,94,2,0,'MIST') - 16-Jun-2016 - Not Made Public: - Fix plot engine to match newer MatPlotLib version MIST Version (0,94,1,0,'MIST') - 30-Aug-2015 - Not Made Public: - Minor fix in text in a comment in a generated file MIST Version (0,94,0,0,'MIST') - 25-Jun-2015 - Not Made Public: - External function interface added - Minor GUI Fixes MIST Version (0,93,2,0,'MIST') - 29-May-2015 - Not Made Public: - Population naming fixed MIST Version (0,93,1,0,'MIST') - 28-May-2015 - Not Made Public: - Cluster Run fixed for grouping with multiple repetitions - Population naming defined for on the fly inheritance - Fixes in reconstructing file with population inheritance MIST Version (0,93,0,0,'MIST') - 06-Mar-2015 - Not Made Public: - Added object oriented population inheritance - Table function short form added - Batch job execution optimized and jobs can be gathered together - Limited backwards compatibility due to changes in definitions MIST Version (0,92,0,0,'MIST') - 27-Aug-2014: - Fix project and rule related issues including undo, occurrence probability and single individual simulation - Installation with dependencies through binstar.org - Fix compatibility issues on Linux - mainly GUI MIST Version (0,91,0,0,'MIST') - 08-Apr-2014: - Better recovery of cluster runs by rerunning and skipping completed jobs - Fix population generation with bound check warnings dropping individuals and evolutionary optimization MIST Version (0,90,0,0,'MIST') - 24-Feb-2014: - Improved population generation with genetic algorithm optimization towards objectives - Improved instructions for cloud deployment - Upgrade to higher versions of supporting packages MIST Version (0,89,0,0,'MIST') - 16-Sep-2013: - Speed up by reducing NFS I/O on the cloud, parallelism, auto temp file removals - Reorganization of cluster run script to separate data and code and allow rerunning portions of a run - Documentation and test code adjustments MIST Version (0,88,0,0,'MIST') - 31-Jul-2013: - Redefinition of Table function to improve speed and remove previous issues - Documentation adjusted with additions to running MIST over the cloud - GUI Bug fix MIST Version (0,87,0,0,'MIST') - 16-Jun-2013: - Split from IEST : Estimation removed, only Simulation remains - Simplification/improvement of Parameters / Models / Simulation Rules - MIST runs over the cloud and on sun Grid Engine clusters - Reproducibility and traceability were improved - Restructured test suite - Documentation adjusted to the changes MIST is a split from IEST. below are IEST versions: IEST Version (0,85,0,0,'Base') - 27-Feb-2012: - Improvements to validity checks to prevent deadlocking the user due to cyclic references and machine precision issues. - Some internal changes to force deterministic calculation order on simulations. - Documentation and minor changes in command line utilities. IEST Version (0,83,0,0,'Base') - 10-Feb-2012: - Minor improvements to validity checks and error messages to improve user experience - Minor GUI improvements - Minor improvements to cluster run, and other utilities and a new utility to support conversion from documentation IEST Version (0,82,0,0,'Base') - 10-Jan-2012: - Minor GUI fixes to display well on multiple resolutions - Minor improvement in DB test script IEST Version (0,81,0,0,'Base') - 21-Dec-2011: - Proper NaN initialization in reports allows better tracking of missing values - Some minor GUI improvements allow easier viewing or long project rule functions - Creating csv report is much faster for many repetitions - The system now support generating plots of simulation results as pdf files using matplotlib IEST Version (0,80,0,0,'Base') - 16-May-2011: - The system requires Python 2.7. Previous python versions are no longer supported. - The system can run simulations in parallel on a cluster using slurm - The report system includes new calculations, stratification, and NaN represents missing values - The system supports loading and saving report options - The system supports simulation with population sets defined by distribution - Inf or inf and NaN or nan can be used in user expressions IEST Version (0,78,0,0,'Base') - 2-Sep-2010: - The system was tested with Python 2.6 - Simulation, population, and report generation through the GUI can be canceled if using python 2.6 on Linux - Special characters will now display with escape codes in systems that do not support them - It is not possible to delete a parameter in a child form of a project form - The Population data form can handle long expression - CSV report is now constructed transposed to make it easier to read - CSV report assembly added - Instructional videos were added to the documentation IEST Version (0,75,0,0,'Base') - 05-May-2010: - Simulation and generation code was modified to: * expand expressions and allow proper intermediate validation of user defined functions. - GUI was fixed to: * avoid listbox text length limitation on Windows to affect rule data entry * bring proper help page in simulation * support top down functionality * properly handle the case where the user declines loading results from a previous version - Documentation was updated to: * show the difference between user defined parameter functions and assignments to parameters IEST Version (0,70,0,0,'Base') - 11-Dec-2009: - Estimation Engine implemented in Python - Code tested on Linux (Debian with appropriate libraries installed) - Some minor fixes in the GUI - Some modifications to make initial population generation less strict: 1) allowing to use the IndividualID parameter as a counter during population generation from distributions. 2) Ignoring inconsistencies between states and sub-processes in the Entered and User manipulated state indicators. - File Version control added - Documentation updated IEST Version 0.60 - 15-Feb-2009: - First release 7. CONTACT INFORMATION AND SUPPORT: SUPPORT MAILING LIST: Email address: [email protected] Archives: https://simtk.org/pipermail/mist-support/ GitHub Project site: https://github.com/Jacob-Barhak/MIST SimTK Project site: https://simtk.org/home/mist DEVELOPER CONTACT INFO: Jacob Barhak Ph.D. Email: [email protected] http://sites.google.com/site/jacobbarhak/ 8. ACKNOWLEDGEMENTS: Special thanks to the pioneers who started this project and dreamed of a modeling framework before I joined the effort: Deanna Isaman - Who was the spirit behind the great ideas I am pursuing and who taught me my first steps in disease modeling Morton Brown - Who provided guidance and challenged the system to improve and by this shaped important concepts in the system William H. Herman - Who provided expert advice regarding disease modeling and opened opportunities in the disease modeling world Aaron Lee Garrett - Who developed Inspyred and was extremely helpful by assisting and consulting me on how to best use this library to enhance population generation capabilities. Many thanks to the creators of Python, WxPython, NumPy, and SciPy that publicly released their work. Specifically, the code uses examples released by WxPython documentation and demo. These examples were extremely helpful in speeding up the development. Special thanks to the following (in no particular order) for their help in various stages of this work: Honghong Zhou Fredric Isaman Shari Messinger Cayetano Michael Brandle The Michigan Python Users Group The Center for Advanced Computing at the University of Michigan Chris Scheller Wen Ye Donghee Lee Ray Lillywhite Aidan Feldman Michael Kylman Continuum Analytics: specifically Ben Zaitlen, Ilan Schnell, Siu Kwan Lam Jonathan Rocher StarCluster team at MIT Sun Grid Engine Robin Dunn Rayson Ho Bruce Fields Nick Coghlan Lyn Gerner @scrappythekangaroo at github Anna Petrasova Nathan McCorkle Werner F. Bruhin Matthew Rocklin MIST was developed independently without financial support. Previous Sponsors of IEST: This work was supported by the National Institutes of Health through the Biostatistics Core of the Michigan Diabetes Research and Training Center under Grant P60-DK-20572, and through grant R21-DK075077 "Chronic Disease Modeling for Clinical Research Innovations" by the National Institutes of Health. 9. LICENSE: Copyright (C) 2013-2014 Jacob Barhak Copyright (C) 2009-2012 The Regents of the University of Michigan This file is part of the MIcroSimulation Tool (MIST). The MIcroSimulation Tool (MIST) is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. The MIcroSimulation Tool (MIST) is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ADDITIONAL CLARIFICATION The MIcroSimulation Tool (MIST) is distributed in the hope that it will be useful, but "as is" and WITHOUT ANY WARRANTY of any kind, including any warranty that it will not infringe on any property rights of another party or the IMPLIED WARRANTIES OF MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. THE AUTHORS assume no responsibilities with respect to the use of the MIcroSimulation Tool (MIST). The MIcroSimulation Tool (MIST) was derived from the Indirect Estimation and Simulation Tool (IEST) and uses code distributed under the IEST name. The change of the name signifies a split from the original design that focuses on microsimulation. For the sake of completeness, the copyright statement from the original tool developed by the University of Michigan is provided below and is also mentioned above. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%% Original Copyright %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Copyright (C) 2009-2012 The Regents of the University of Michigan Initially developed by Deanna Isaman, Jacob Barhak, Morton Brown, Wen Ye Additional coding by Donghee Lee, Ray Lillywhite, Aidan Feldman Videos by Michael Kylman This file is part of the Indirect Estimation and Simulation Tool (IEST). The Indirect Estimation and Simulation Tool (IEST) is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. The Indirect Estimation and Simulation Tool (IEST) is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ADDITIONAL CLARIFICATION The Indirect Estimation and Simulation Tool (IEST) is distributed in the hope that it will be useful, but "as is" and WITHOUT ANY WARRANTY of any kind, including any warranty that it will not infringe on any property rights of another party or the IMPLIED WARRANTIES OF MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. THE UNIVERSITY OF MICHIGAN assumes no responsibilities with respect to the use of the Indirect Estimation and Simulation Tool (IEST). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%% End Of Original Copyright %%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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