| 1-2 |
Introduction: problem formulation, algorithm development, algorithm implementation, and algorithm verification. Structure and documentation |
Lecture 1 (PDF)
Lecture 2 (PDF)
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Lecture 1
Class introduction; overview of languages; program development.
Lecture 2
Discussion of aspects of computers and their operation. An example is given of program development for a simple case of computing the area of a figure.
In the lecture notes the poly_area.f (F) FORTRAN program is referred to. This program implements the area determination algorithm discussed in the lecture.
Links that are in the notes for this lecture:
What is big-endian?
Green's Theorem
The IEEE standard for floating point arithmetic
Minor links for those interested:
Velocity Engine
Z80 Instructions
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| 3-7 |
FORTRAN: "Formula Translation". Program creation, compilation and linking, variables and parameters, flow control, subroutines and functions. Structure and documentation. Use of libraries, internal and external communication, and interaction with other languages. FORTRAN: implementation issues: compilation errors, segmentation violations, Not-a-Number (NaN), Input/Output (IOSTAT) errors, Runtime errors. Transportable code, standard extensions. FORTRAN 90 differences and similarities to FORTRAN 77 |
Lecture 3 (PDF)
Lecture 4 (PDF)
Lecture 5 (PDF)
Lecture 6 (PDF)
Lecture 7 (PDF)
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Lecture 3
Started FORTRAN (Formula Translation). Went through the basic elements that make up this language. An on-line version of a FORTRAN 77 manual can be found here. In reading these notes, you should think about operations you want to do and what command or commands do you use to do that. The list on FORTRAN intrinsic functions can be found here.
Other links to look at:
The FORTRAN Programming Language
Wikipedia Definition of FORTRAN
Lecture 4
Continued with showing the elements of the FORTRAN and more detail on the typically encountered features of the language. Topics covered: subroutines and functions; intrinsic functions; constants and variables; input output with open/close, read/write, formats; character strings.
The links in this lecture were to FORTRAN and intrinsic functions, which are given above. The programs poly_area.f (F) and vars.f (F) are also used. (To download programs, right click on link and "save link target as". With one-button mouse use <ctrl><click> on link). On Athena to use these programs:
ssh –X linerva.mit.edu
%add fortran
%f77 poly_area.f –o poly_area
% poly_area
To use the f90 compiler on Athena, use add sunsoft.
Other sources of information:
Safari Book Online - O'Reilly series of books on programming (available with MIT certificate)
FORTRAN Resources - useful link with lots of information on FORTRAN in its various forms
Lecture 5
Continued with FORTRAN. Character strings, control statements if and do; other commands such as include, common, parameter. More programs will be developed in class including simple output and computing root-mean-square scatter of randomly generated numbers. Program developed in class: rms.f (F)
Lecture 6
Finish up FORTRAN. Compile, linking and runtime errors and miscellaneous topics. Practice with using the language.
Lecture 7
Examines the changes that were made in FORTRAN90 with the introductions on more modern concepts in programming languages.
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| 8-11 |
C for scientific uses. Representation of data through arrays, pointers, and data structures. Function calls, argument passing and scoping rules, IO, profiling, system calls, and signals
C++ objects. Encapsulation and inheritance, polymorphic operators
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Lecture 8 (PDF)
Lecture 9 (PDF)
Lecture 10 (PDF)
Lecture 11 (PDF)
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Lecture 8
Start of C-language programming. History, variables and executable statements.
Additional links for this class:
Basic C Lecture
Basic C: C and FORTRAN 77 Syntax
Basic C: New Features
Lecture 08 Exercises.
Basic C Lecture
Lecture 9
Continuation of C. Covering Examined C-pointer; file Input/Output and the routines for formatted reads and write; compiling C routines; the C preprocessor cpp; structures in C; memory management.
Lec09_pnt.c (C) is demonstration of pointers
Lecture 10
Finish structures and memory management in C. Start of C++. Inheritance and overloading in C++.
C and C++ routines used in class launch.c (C)
Ball.h (H) and launch.cc (CC)
C++ zip files:
ustring.zip (ZIP) (The ZIP file contains: 2 .h, 1 .cc, and 1 .txt file.)
launch.zip (ZIP) (The ZIP file contains: 1 .cc, 1 .h, and 1 .txt file.)
coord.zip (ZIP) (The ZIP file contains: 1 .cc, 1 .h, and 1 .txt file.)
Lecture 11
Finish up of C++ looking at classes, inheritance and overloading. We will look more carefully at the code linked in Lecture 10. Homework number 3 has been set.
Example pieces of code for C and comparison to FORTRAN:
C basics (PDF), area.c (C), hello.c (C)
C FORTRAN compare (PDF)
C pointers (PDF)
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| 12-13 |
Mathematica. What it is and what it can do; structure of Mathematica; symbols, exact numbers, and machine numbers; lists, vectors, and matrices
Working with Mathematica: numerical calculations, symbolic calculations, and graphics. Importing and exporting information
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Lecture 12 (PDF)
Lecture 13 (PDF)
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Lecture 12
Start of Mathematica. These lectures are accompanied by a Mathematica Notebook that shows example of concepts presented in the notes.
Lec 12 NB (NB)
Introductory screen casts from Wolfram:
Introduction
Making Models
Use of the demonstrations site
Featured Demonstrations
Lecture 13
Continuation of Mathematica. These lectures are accompanied by a Mathematica notebook that shows example of concepts presented in the notes.
Lec 13 NB (NB)
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| 14-17 |
MATLAB. "Matrix Laboratory". MATLAB syntax, workspace, variables. Script M-files, IO, control flow, debugging, and profiling tools. Object-oriented programming
MATLAB applications, polynomials, interpolation, integration, differentiation, ODE. Graphics, 2-D, 3-D, Graphical User Interface (GUI)
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Lecture 14 (PDF)
Lecture 15 (PDF)
Lecture 16 (PDF)
Lecture 17 (PDF)
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Lecture 14
MATLAB: introductory lecture on MATLAB introducing system, variable types, control and functions. The following MATLAB M-files are used in the lecture:
Lec01_01.m (M)
Lec01_02.m (M)
Lecture 15
MATLAB: path command, variables, file IO and dialog boxes. The following M-files are used:
Lec02_01_file.m (M)
Lec02_02_db.m (M)
Lec03_01_file.m (M)
The data for these M-files can be found in MatData. A tar file with the data is TSeries.tar (TAR) (The TAR file contains: 10 .dat1, 10 .dat2, and 10 .dat3 files.)
Lecture 16
MATLAB: graphics handles and animation of figures. The following M-files are used in class:
Lec03_movie.m (M)
MATLAB/per_func.m (M)
Lecture 17
MATLAB: final class on GUI construction and use. The following M-files are used (along with the data from MatData: a tar file with the data is TSeries.tar (TAR) (The TAR file contains: 10 .dat1, 10 .dat2, and 10 .dat3 files.)
Basic GUI layout:
GPSanal.m (M)
gpsguio.m (M)
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| 18 |
Ordinary differential equation (ODE) solutions used MATLAB and Mathematica |
Lecture 18 (PDF) |
Lecture 18
Solution to differential equations in Mathematica and MATLAB.
Mathematic notebook: 12.010.Lec18_NDsolve.nb (NB)
MATLAB solutions are:
Lec18_ODE.m (M)
Lec18_animate.m (M)
Lec18_hit.m (M)
Lec18_bacc.m (M)
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| 19 |
Advanced graphics in MATLAB, 3-D representation and exportable animations |
Lecture 19 (PDF) |
Lecture 19
3-D graphics in MATLAB.
Examples are:
Lec19_3D.m (M)
Lec19_TotalANC.avi (AVI)
Lec19_RateANC.avi (AVI)
Dif_1006_0407.fig (FIG)
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| 20-23 |
Advanced Topics: Parallel computing with large memory and large numbers of CPUs
Advanced topics: Parallel MATLAB
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Lecture 22 (PDF)
Lecture 23 (PDF)
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Lecture 22
Introduction of class project. Graphics formats and issues about vector and pixel based graphics.
GMT graphics package for mapping applications
Lecture 23
Class projects: graphics processor unit (GPU) processing. Statistics and random number generators. M-file randtest.m (M) is implementation of an LCG random number generator. The order of the class presentations will be decided in this class and posted after the class.
Cuda Zone
MATLAB Implementation
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| 24-25 |
Graphics: review of common graphics program. Graphics with spreadsheets, Kaleidagraph, Generic Mapping Tool (GMT). Numerical methods: introduction to numerical methods
Statistical analysis tools including generation random variables and correlated random numbers
Order of the presentations will be decided in the last class
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Final project presentations |
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