numexercises7_14
Differences
This shows you the differences between two versions of the page.
| Both sides previous revision Previous revision Next revision | Previous revision Next revision Both sides next revision | ||
|
numexercises7_14 [2014/07/14 08:03] bogner |
numexercises7_14 [2014/07/14 08:13] bogner |
||
|---|---|---|---|
| Line 1: | Line 1: | ||
| ===== Numerical Exercises for Monday July 14 ===== | ===== Numerical Exercises for Monday July 14 ===== | ||
| + | * In your favorite programming language, make a program to construct a real symmetric $NxN$ matrix. Diagonalize it using the appropriate LAPACK or GSL routine, and write out some number of the lowest eigenvalues. (Suggestion: You might find it useful to use Mathematica (available on the ECT* computers) to diagonalize a small matrix that you can benchmark against.) This will help you test that you've linked to the GSL or LAPACK library. | ||
| + | |||
| + | * Install Git, and try out some of the commands covered in Morten or Nicolas's lecture slides ({{:computing.pdf|}} {{:talentdftguides.pdf|}}) for your code in the first problem. | ||
| - | - In your favorite programming language, make a program to construct a real $NxN$ matrix. Diagonalize it using the appropriate LAPACK or GSL routine, and write out some number of the lowest eigenvalues. | + | * The code calculates the relative matrix elements $\langle nl|V|n'l\rangle$ in HO states. From this, construct a subroutine that returns the properly normalized $r$-space HO wf's. For some basic background on HO wf's, {{:ho_spherical.pdf| see here}}. |
| - | - Use your simple program as an opportunity to play with Git. Try out some of the commands covered in Morten or Nicolas's lecture slides {{:computing.pdf|}} {{:talentdftguides.pdf|}} | + | |
| + | * | ||
numexercises7_14.txt · Last modified: 2014/07/14 13:40 by bogner
Page Tools
Except where otherwise noted, content on this wiki is licensed under the following license: CC Attribution-Share Alike 4.0 International
