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Merge pull request #1399 from asmeurer/sympyprinting...
Merge pull request #1399 from asmeurer/sympyprinting Use LaTeX to display, on output, various built-in types with the SymPy printing extension. SymPy's latex() function supports printing lists, tuples, and dicts using latex notation (it uses bmatrix, pmatrix, and Bmatrix, respectively). This provides a more unified experience with SymPy functions that return these types (such as solve()). Also display ints, longs, and floats using LaTeX, to get a more unified printing experience (so that, e.g., x/x will print the same as just 1). The string form can always be obtained by manually calling the actual print function, or 2d unicode printing using pprint(). SymPy's latex() function doesn't treat set() or frosenset() correctly presently (see http://code.google.com/p/sympy/issues /detail?id=3062), so for the present, we leave those alone.

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# <nbformat>2</nbformat>
# <markdowncell>
# # Eigenvalue distribution of Gaussian orthogonal random matrices
# <markdowncell>
# The eigenvalues of random matrices obey certain statistical laws. Here we construct random matrices
# from the Gaussian Orthogonal Ensemble (GOE), find their eigenvalues and then investigate the nearest
# neighbor eigenvalue distribution $\rho(s)$.
# <codecell>
from rmtkernel import ensemble_diffs, normalize_diffs, GOE
import numpy as np
from IPython.parallel import Client
# <markdowncell>
# ## Wigner's nearest neighbor eigenvalue distribution
# <markdowncell>
# The Wigner distribution gives the theoretical result for the nearest neighbor eigenvalue distribution
# for the GOE:
#
# $$\rho(s) = \frac{\pi s}{2} \exp(-\pi s^2/4)$$
# <codecell>
def wigner_dist(s):
"""Returns (s, rho(s)) for the Wigner GOE distribution."""
return (np.pi*s/2.0) * np.exp(-np.pi*s**2/4.)
# <codecell>
def generate_wigner_data():
s = np.linspace(0.0,4.0,400)
rhos = wigner_dist(s)
return s, rhos
# <codecell>
s, rhos = generate_wigner_data()
# <codecell>
plot(s, rhos)
xlabel('Normalized level spacing s')
ylabel('Probability $\rho(s)$')
# <markdowncell>
# ## Serial calculation of nearest neighbor eigenvalue distribution
# <markdowncell>
# In this section we numerically construct and diagonalize a large number of GOE random matrices
# and compute the nerest neighbor eigenvalue distribution. This comptation is done on a single core.
# <codecell>
def serial_diffs(num, N):
"""Compute the nearest neighbor distribution for num NxX matrices."""
diffs = ensemble_diffs(num, N)
normalized_diffs = normalize_diffs(diffs)
return normalized_diffs
# <codecell>
serial_nmats = 1000
serial_matsize = 50
# <codecell>
%timeit -r1 -n1 serial_diffs(serial_nmats, serial_matsize)
# <codecell>
serial_diffs = serial_diffs(serial_nmats, serial_matsize)
# <markdowncell>
# The numerical computation agrees with the predictions of Wigner, but it would be nice to get more
# statistics. For that we will do a parallel computation.
# <codecell>
hist_data = hist(serial_diffs, bins=30, normed=True)
plot(s, rhos)
xlabel('Normalized level spacing s')
ylabel('Probability $P(s)$')
# <markdowncell>
# ## Parallel calculation of nearest neighbor eigenvalue distribution
# <markdowncell>
# Here we perform a parallel computation, where each process constructs and diagonalizes a subset of
# the overall set of random matrices.
# <codecell>
def parallel_diffs(rc, num, N):
nengines = len(rc.targets)
num_per_engine = num/nengines
print "Running with", num_per_engine, "per engine."
ar = rc.apply_async(ensemble_diffs, num_per_engine, N)
diffs = np.array(ar.get()).flatten()
normalized_diffs = normalize_diffs(diffs)
return normalized_diffs
# <codecell>
client = Client()
view = client[:]
view.run('rmtkernel.py')
view.block = False
# <codecell>
parallel_nmats = 40*serial_nmats
parallel_matsize = 50
# <codecell>
%timeit -r1 -n1 parallel_diffs(view, parallel_nmats, parallel_matsize)
# <codecell>
pdiffs = parallel_diffs(view, parallel_nmats, parallel_matsize)
# <markdowncell>
# Again, the agreement with the Wigner distribution is excellent, but now we have better
# statistics.
# <codecell>
hist_data = hist(pdiffs, bins=30, normed=True)
plot(s, rhos)
xlabel('Normalized level spacing s')
ylabel('Probability $P(s)$')