Difference between revisions of "Simulationsmethoden I WS 09 10"
(→Simulationsmethoden in der Physik I:Simulation Methods in Physics I) 
Tabatabaei (talk  contribs) (→Tutorials (U 108)) 

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Line 3:  Line 3:  
;Type  ;Type  
−  :Lecture (2 SWS) and Tutorials (  +  :Lecture (2 SWS) and Tutorials (1 SWS) 
−  :  +  : 
;Lecturer  ;Lecturer  
:Prof. Dr. [[Christian Holm]] (Lecture) and [[Joan Josep Cerdà]], [[Fatemeh Tabatabaei]], [[Nadezhda Gribova]] (Tutorials)  :Prof. Dr. [[Christian Holm]] (Lecture) and [[Joan Josep Cerdà]], [[Fatemeh Tabatabaei]], [[Nadezhda Gribova]] (Tutorials)  
Line 10:  Line 10:  
:Deutsch oder Englisch, wie gewünscht German or English, by vote  :Deutsch oder Englisch, wie gewünscht German or English, by vote  
;Time and Room  ;Time and Room  
−  :Lecture times:  +  :Lecture times: Monday, 11:30 a.m.1 p.m., Room V27.03 (tentative), 
+  :Tutorial times: Wednesday, 3:30 p.m.5:30 p.m., Room U 108 (Pfaffenwaldring 27)  
The lecture is accompanied by handsontutorials which will take place in the CIPPool of the ICP, Pfaffenwaldring 27, U 108. They consist of practical exercises at the computer, like small programming tasks, simulations, visualization and data analysis.  The lecture is accompanied by handsontutorials which will take place in the CIPPool of the ICP, Pfaffenwaldring 27, U 108. They consist of practical exercises at the computer, like small programming tasks, simulations, visualization and data analysis.  
The tutorials build on each other, therefore continuous attendance is expected.  The tutorials build on each other, therefore continuous attendance is expected.  
−  Tutorials will be hold on: Time to be  +  Tutorials will be hold on: Time to be negotiated during the first meeting on October 19. 
==Scope==  ==Scope==  
−  The course  +  
+  The course intends to give an overview about modern simulation methods  
+  used in physics today. The stress of the lecture will be to introduce different  
+  approaches to simulate a problem, hence we will not go too to deep into specific details but rather try to cover a broad range of methods. In more detail, the  
+  lecture will consist of:  
+  
+  '''1. Molecular Dynamics'''  
+  
+  The first problem that comes to mind when thinking about simulating  
+  physics is solving Newtons equations of motion for some particles with  
+  given interactions. From that perspective, we first introduce the most  
+  common numerical integrators. This approach quickly leads us to  
+  Molecular Dynamics (MD) simulations. Many of the complex problems of  
+  practical importance require us to take a closer look at statistical  
+  properties, ensembles and the macroscopic observables.  
+  
+  The goal is to be able to set up and run real MD simulations for  
+  different ensembles and understand and interpret the output.  
+  
+  '''2. Partial Differential Equations'''  
+  
+  Some of the most common physical problems today can be formulated with  
+  Partial Differential Equations (PDEs). We want to think about what kinds  
+  of physical problems can be dealt with PDEs and what methods we  
+  have to solve them numerically.  
+  
+  The goal is to get to know the problems you run into when solving these  
+  simplelooking equations and to get an overview on the methods available.  
+  
+  '''3. Quantum mechanical systems'''  
+  
+  It is obvious that solving quantum mechanical systems analytically is not possible and we need numerical help. We want to introduce various methods like (post)HartreeFock, Density Functional Theory, and CarParrinelloMolecular dynamics. We also want to examine the possibilities to simulate the quantum chromodynamics PDEs on a lattice (lattice gauge theory).  
+  
+  The goal is to get an overview on the methods to treat quantum  
+  mechanical systems and know about some of the advantages and  
+  disadvantages of each method.  
+  
+  '''4. Monte Carlo Simulations'''  
+  
+  Since their invention, the importance of Monte Carlo (MC) sampling has  
+  grown constantly. Nowadays it is applied to a wide class of problems in modern  
+  computational physics. We want to present the general idea and theory  
+  behind MC simulations and show some more properties using simple toy models  
+  like the Isingmodel.  
== Prerequisites ==  == Prerequisites ==  
Line 29:  Line 73:  
valign="top"  valign="top"  
!Date !! Subject  !Date !! Subject  
−  +    
+   19.10.09  Contents, introduction, organisation  
}  }  
Line 37:  Line 82:  
valign="top"  valign="top"  
!Date !! Subject  !Date !! Subject  
−  +    
+  21.10.09  First steps with Linux and C  
+    
+  28.10.09  [[Equations of motion and integrators]]  
+    
+  11.11.09  [[Molecular Dynamics: LennardJones liquid]]  
+    
+  25.11.09  [[MD in NVE and NVT ensembles; implementing different thermostats]]  
+    
+  09.12.09  [[The finite Difference and Finite element methods]]  
+    
+  23.12.09  [[Numerical Solution of the Schroedinger Equation]]  
+    
+  20.01.09  [[Simple and important sampling. Random walks.]]  
+    
+  04.02.09  [[Monte CarloIsing model]]  
}  }  
Latest revision as of 14:30, 1 February 2010
Contents
Overview
Simulationsmethoden in der Physik I:Simulation Methods in Physics I
 Type
 Lecture (2 SWS) and Tutorials (1 SWS)
 Lecturer
 Prof. Dr. Christian Holm (Lecture) and Joan Josep Cerdà, Fatemeh Tabatabaei, Nadezhda Gribova (Tutorials)
 Course language
 Deutsch oder Englisch, wie gewünscht German or English, by vote
 Time and Room
 Lecture times: Monday, 11:30 a.m.1 p.m., Room V27.03 (tentative),
 Tutorial times: Wednesday, 3:30 p.m.5:30 p.m., Room U 108 (Pfaffenwaldring 27)
The lecture is accompanied by handsontutorials which will take place in the CIPPool of the ICP, Pfaffenwaldring 27, U 108. They consist of practical exercises at the computer, like small programming tasks, simulations, visualization and data analysis. The tutorials build on each other, therefore continuous attendance is expected. Tutorials will be hold on: Time to be negotiated during the first meeting on October 19.
Scope
The course intends to give an overview about modern simulation methods used in physics today. The stress of the lecture will be to introduce different approaches to simulate a problem, hence we will not go too to deep into specific details but rather try to cover a broad range of methods. In more detail, the lecture will consist of:
1. Molecular Dynamics
The first problem that comes to mind when thinking about simulating physics is solving Newtons equations of motion for some particles with given interactions. From that perspective, we first introduce the most common numerical integrators. This approach quickly leads us to Molecular Dynamics (MD) simulations. Many of the complex problems of practical importance require us to take a closer look at statistical properties, ensembles and the macroscopic observables.
The goal is to be able to set up and run real MD simulations for different ensembles and understand and interpret the output.
2. Partial Differential Equations
Some of the most common physical problems today can be formulated with Partial Differential Equations (PDEs). We want to think about what kinds of physical problems can be dealt with PDEs and what methods we have to solve them numerically.
The goal is to get to know the problems you run into when solving these simplelooking equations and to get an overview on the methods available.
3. Quantum mechanical systems
It is obvious that solving quantum mechanical systems analytically is not possible and we need numerical help. We want to introduce various methods like (post)HartreeFock, Density Functional Theory, and CarParrinelloMolecular dynamics. We also want to examine the possibilities to simulate the quantum chromodynamics PDEs on a lattice (lattice gauge theory).
The goal is to get an overview on the methods to treat quantum mechanical systems and know about some of the advantages and disadvantages of each method.
4. Monte Carlo Simulations
Since their invention, the importance of Monte Carlo (MC) sampling has grown constantly. Nowadays it is applied to a wide class of problems in modern computational physics. We want to present the general idea and theory behind MC simulations and show some more properties using simple toy models like the Isingmodel.
Prerequisites
We expect the participants to have basic knowledge in classical and statistical mechanics, thermodynamics, electrodynamics, and partial differential equations, as well as knowledge of a programming language (preferably C or C++).
Certificate Requirements:
 1. Attendance of the exercise classes
 2. Obtaining 50% of the possible marks in the handin exercises
Lecture
Date  Subject 

19.10.09  Contents, introduction, organisation 
Tutorials (U 108)
Date  Subject 

21.10.09  First steps with Linux and C 
28.10.09  Equations of motion and integrators 
11.11.09  Molecular Dynamics: LennardJones liquid 
25.11.09  MD in NVE and NVT ensembles; implementing different thermostats 
09.12.09  The finite Difference and Finite element methods 
23.12.09  Numerical Solution of the Schroedinger Equation 
20.01.09  Simple and important sampling. Random walks. 
04.02.09  Monte CarloIsing model 
Recommended literature

Daan Frenkel and Berend Smit.
"Understanding Molecular Simulation".
Academic Press, San Diego, 2002.
[DOI] 
Mike P. Allen and Dominik J. Tildesley.
"Computer Simulation of Liquids".
Oxford Science Publications, Clarendon Press, Oxford, 1987.

D. C. Rapaport.
"The Art of Molecular Dynamics Simulation".
Cambridge University Press, 2004.

D. P. Landau and K. Binder.
"A guide to Monte Carlo Simulations in Statistical Physics".
Cambridge, 2005.

M. E. J. Newman and G. T. Barkema.
"Monte Carlo Methods in Statistical Physics".
Oxford University Press, 1999.
Available EBooks
D.P. Landau and K. Binder.