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PDE_FIND.py
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PDE_FIND.py
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import numpy as np
from numpy import linalg as LA
import scipy.sparse as sparse
from scipy.sparse import csc_matrix
from scipy.sparse import dia_matrix
import itertools
import operator
"""
A few functions used in PDE-FIND
Samuel Rudy. 2016
"""
##################################################################################
##################################################################################
#
# Functions for taking derivatives.
# When in doubt / nice data ===> finite differences
# \ noisy data ===> polynomials
#
##################################################################################
##################################################################################
def TikhonovDiff(f, dx, lam, d = 1):
"""
Tikhonov differentiation.
return argmin_g \|Ag-f\|_2^2 + lam*\|Dg\|_2^2
where A is trapezoidal integration and D is finite differences for first dervative
It looks like it will work well and does for the ODE case but
tends to introduce too much bias to work well for PDEs. If the data is noisy, try using
polynomials instead.
"""
# Initialize a few things
n = len(f)
f = np.matrix(f - f[0]).reshape((n,1))
# Get a trapezoidal approximation to an integral
A = np.zeros((n,n))
for i in range(1, n):
A[i,i] = dx/2
A[i,0] = dx/2
for j in range(1,i): A[i,j] = dx
e = np.ones(n-1)
D = sparse.diags([e, -e], [1, 0], shape=(n-1, n)).todense() / dx
# Invert to find derivative
g = np.squeeze(np.asarray(np.linalg.lstsq(A.T.dot(A) + lam*D.T.dot(D),A.T.dot(f))[0]))
if d == 1: return g
# If looking for a higher order derivative, this one should be smooth so now we can use finite differences
else: return FiniteDiff(g, dx, d-1)
def FiniteDiff(u, dx, d):
"""
Takes dth derivative data using 2nd order finite difference method (up to d=3)
Works but with poor accuracy for d > 3
Input:
u = data to be differentiated
dx = Grid spacing. Assumes uniform spacing
"""
n = u.size
ux = np.zeros(n, dtype=np.complex64)
if d == 1:
for i in range(1,n-1):
ux[i] = (u[i+1]-u[i-1]) / (2*dx)
ux[0] = (-3.0/2*u[0] + 2*u[1] - u[2]/2) / dx
ux[n-1] = (3.0/2*u[n-1] - 2*u[n-2] + u[n-3]/2) / dx
return ux
if d == 2:
for i in range(1,n-1):
ux[i] = (u[i+1]-2*u[i]+u[i-1]) / dx**2
ux[0] = (2*u[0] - 5*u[1] + 4*u[2] - u[3]) / dx**2
ux[n-1] = (2*u[n-1] - 5*u[n-2] + 4*u[n-3] - u[n-4]) / dx**2
return ux
if d == 3:
for i in range(2,n-2):
ux[i] = (u[i+2]/2-u[i+1]+u[i-1]-u[i-2]/2) / dx**3
ux[0] = (-2.5*u[0]+9*u[1]-12*u[2]+7*u[3]-1.5*u[4]) / dx**3
ux[1] = (-2.5*u[1]+9*u[2]-12*u[3]+7*u[4]-1.5*u[5]) / dx**3
ux[n-1] = (2.5*u[n-1]-9*u[n-2]+12*u[n-3]-7*u[n-4]+1.5*u[n-5]) / dx**3
ux[n-2] = (2.5*u[n-2]-9*u[n-3]+12*u[n-4]-7*u[n-5]+1.5*u[n-6]) / dx**3
return ux
if d > 3:
return FiniteDiff(FiniteDiff(u,dx,3), dx, d-3)
def ConvSmoother(x, p, sigma):
"""
Smoother for noisy data
Inpute = x, p, sigma
x = one dimensional series to be smoothed
p = width of smoother
sigma = standard deviation of gaussian smoothing kernel
"""
n = len(x)
y = np.zeros(n, dtype=np.complex64)
g = np.exp(-np.power(np.linspace(-p,p,2*p),2)/(2.0*sigma**2))
for i in range(n):
a = max([i-p,0])
b = min([i+p,n])
c = max([0, p-i])
d = min([2*p,p+n-i])
y[i] = np.sum(np.multiply(x[a:b], g[c:d]))/np.sum(g[c:d])
return y
def PolyDiff(u, x, deg = 3, diff = 1, width = 5):
"""
u = values of some function
x = x-coordinates where values are known
deg = degree of polynomial to use
diff = maximum order derivative we want
width = width of window to fit to polynomial
This throws out the data close to the edges since the polynomial derivative only works
well when we're looking at the middle of the points fit.
"""
u = u.flatten()
x = x.flatten()
n = len(x)
du = np.zeros((n - 2*width,diff))
# Take the derivatives in the center of the domain
for j in range(width, n-width):
points = np.arange(j - width, j + width)
# Fit to a Chebyshev polynomial
# this is the same as any polynomial since we're on a fixed grid but it's better conditioned :)
poly = np.polynomial.chebyshev.Chebyshev.fit(x[points],u[points],deg)
# Take derivatives
for d in range(1,diff+1):
du[j-width, d-1] = poly.deriv(m=d)(x[j])
return du
def PolyDiffPoint(u, x, deg = 3, diff = 1, index = None):
"""
Same as above but now just looking at a single point
u = values of some function
x = x-coordinates where values are known
deg = degree of polynomial to use
diff = maximum order derivative we want
"""
n = len(x)
if index == None: index = (n-1)/2
# Fit to a Chebyshev polynomial
# better conditioned than normal polynomials
poly = np.polynomial.chebyshev.Chebyshev.fit(x,u,deg)
# Take derivatives
derivatives = []
for d in range(1,diff+1):
derivatives.append(poly.deriv(m=d)(x[index]))
return derivatives
##################################################################################
##################################################################################
#
# Functions specific to PDE-FIND
#
##################################################################################
##################################################################################
def build_Theta(data, derivatives, derivatives_description, P, data_description = None):
"""
builds a matrix with columns representing polynoimials up to degree P of all variables
This is used when we subsample and take all the derivatives point by point or if there is an
extra input (Q in the paper) to put in.
input:
data: column 0 is U, and columns 1:end are Q
derivatives: a bunch of derivatives of U and maybe Q, should start with a column of ones
derivatives_description: description of what derivatives have been passed in
P: max power of polynomial function of U to be included in Theta
returns:
Theta = Theta(U,Q)
descr = description of what all the columns in Theta are
"""
n,d = data.shape
m, d2 = derivatives.shape
if n != m: raise Exception('dimension error')
if data_description is not None:
if len(data_description) != d: raise Exception('data descrption error')
# Create a list of all polynomials in d variables up to degree P
rhs_functions = {}
f = lambda x, y : np.prod(np.power(list(x), list(y)))
powers = []
for p in range(1,P+1):
size = d + p - 1
for indices in itertools.combinations(range(size), d-1):
starts = [0] + [index+1 for index in indices]
stops = indices + (size,)
powers.append(tuple(map(operator.sub, stops, starts)))
for power in powers: rhs_functions[power] = [lambda x, y = power: f(x,y), power]
# First column of Theta is just ones.
Theta = np.ones((n,1), dtype=np.complex64)
descr = ['']
# Add the derivaitves onto Theta
for D in range(1,derivatives.shape[1]):
Theta = np.hstack([Theta, derivatives[:,D].reshape(n,1)])
descr.append(derivatives_description[D])
# Add on derivatives times polynomials
for D in range(derivatives.shape[1]):
for k in rhs_functions.keys():
func = rhs_functions[k][0]
new_column = np.zeros((n,1), dtype=np.complex64)
for i in range(n):
new_column[i] = func(data[i,:])*derivatives[i,D]
Theta = np.hstack([Theta, new_column])
if data_description is None: descr.append(str(rhs_functions[k][1]) + derivatives_description[D])
else:
function_description = ''
for j in range(d):
if rhs_functions[k][1][j] != 0:
if rhs_functions[k][1][j] == 1:
function_description = function_description + data_description[j]
else:
function_description = function_description + data_description[j] + '^' + str(rhs_functions[k][1][j])
descr.append(function_description + derivatives_description[D])
return Theta, descr
def build_linear_system(u, dt, dx, D = 3, P = 3,time_diff = 'poly',space_diff = 'poly',lam_t = None,lam_x = None, width_x = None,width_t = None, deg_x = 5,deg_t = None,sigma = 2):
"""
Constructs a large linear system to use in later regression for finding PDE.
This function works when we are not subsampling the data or adding in any forcing.
Input:
Required:
u = data to be fit to a pde
dt = temporal grid spacing
dx = spatial grid spacing
Optional:
D = max derivative to include in rhs (default = 3)
P = max power of u to include in rhs (default = 3)
time_diff = method for taking time derivative
options = 'poly', 'FD', 'FDconv','TV'
'poly' (default) = interpolation with polynomial
'FD' = standard finite differences
'FDconv' = finite differences with convolutional smoothing
before and after along x-axis at each timestep
'Tik' = Tikhonov (takes very long time)
space_diff = same as time_diff with added option, 'Fourier' = differentiation via FFT
lam_t = penalization for L2 norm of second time derivative
only applies if time_diff = 'TV'
default = 1.0/(number of timesteps)
lam_x = penalization for L2 norm of (n+1)st spatial derivative
default = 1.0/(number of gridpoints)
width_x = number of points to use in polynomial interpolation for x derivatives
or width of convolutional smoother in x direction if using FDconv
width_t = number of points to use in polynomial interpolation for t derivatives
deg_x = degree of polynomial to differentiate x
deg_t = degree of polynomial to differentiate t
sigma = standard deviation of gaussian smoother
only applies if time_diff = 'FDconv'
default = 2
Output:
ut = column vector of length u.size
R = matrix with ((D+1)*(P+1)) of column, each as large as ut
rhs_description = description of what each column in R is
"""
n, m = u.shape
if width_x == None: width_x = n/10
if width_t == None: width_t = m/10
if deg_t == None: deg_t = deg_x
# If we're using polynomials to take derviatives, then we toss the data around the edges.
if time_diff == 'poly':
m2 = m-2*width_t
offset_t = width_t
else:
m2 = m
offset_t = 0
if space_diff == 'poly':
n2 = n-2*width_x
offset_x = width_x
else:
n2 = n
offset_x = 0
if lam_t == None: lam_t = 1.0/m
if lam_x == None: lam_x = 1.0/n
########################
# First take the time derivaitve for the left hand side of the equation
########################
ut = np.zeros((n2,m2), dtype=np.complex64)
if time_diff == 'FDconv':
Usmooth = np.zeros((n,m), dtype=np.complex64)
# Smooth across x cross-sections
for j in range(m):
Usmooth[:,j] = ConvSmoother(u[:,j],width_t,sigma)
# Now take finite differences
for i in range(n2):
ut[i,:] = FiniteDiff(Usmooth[i + offset_x,:],dt,1)
elif time_diff == 'poly':
T= np.linspace(0,(m-1)*dt,m)
for i in range(n2):
ut[i,:] = PolyDiff(u[i+offset_x,:],T,diff=1,width=width_t,deg=deg_t)[:,0]
elif time_diff == 'Tik':
for i in range(n2):
ut[i,:] = TikhonovDiff(u[i + offset_x,:], dt, lam_t)
else:
for i in range(n2):
ut[i,:] = FiniteDiff(u[i + offset_x,:],dt,1)
ut = np.reshape(ut, (n2*m2,1), order='F')
########################
# Now form the rhs one column at a time, and record what each one is
########################
u2 = u[offset_x:n-offset_x,offset_t:m-offset_t]
Theta = np.zeros((n2*m2, (D+1)*(P+1)), dtype=np.complex64)
ux = np.zeros((n2,m2), dtype=np.complex64)
rhs_description = ['' for i in range((D+1)*(P+1))]
if space_diff == 'poly':
Du = {}
for i in range(m2):
Du[i] = PolyDiff(u[:,i+offset_t],np.linspace(0,(n-1)*dx,n),diff=D,width=width_x,deg=deg_x)
if space_diff == 'Fourier': ik = 1j*np.fft.fftfreq(n)*n
for d in range(D+1):
if d > 0:
for i in range(m2):
if space_diff == 'Tik': ux[:,i] = TikhonovDiff(u[:,i+offset_t], dx, lam_x, d=d)
elif space_diff == 'FDconv':
Usmooth = ConvSmoother(u[:,i+offset_t],width_x,sigma)
ux[:,i] = FiniteDiff(Usmooth,dx,d)
elif space_diff == 'FD': ux[:,i] = FiniteDiff(u[:,i+offset_t],dx,d)
elif space_diff == 'poly': ux[:,i] = Du[i][:,d-1]
elif space_diff == 'Fourier': ux[:,i] = np.fft.ifft(ik**d*np.fft.fft(ux[:,i]))
else: ux = np.ones((n2,m2), dtype=np.complex64)
for p in range(P+1):
Theta[:, d*(P+1)+p] = np.reshape(np.multiply(ux, np.power(u2,p)), (n2*m2), order='F')
if p == 1: rhs_description[d*(P+1)+p] = rhs_description[d*(P+1)+p]+'u'
elif p>1: rhs_description[d*(P+1)+p] = rhs_description[d*(P+1)+p]+'u^' + str(p)
if d > 0: rhs_description[d*(P+1)+p] = rhs_description[d*(P+1)+p]+\
'u_{' + ''.join(['x' for _ in range(d)]) + '}'
return ut, Theta, rhs_description
def print_pde(w, rhs_description, ut = 'u_t'):
pde = ut + ' = '
first = True
for i in range(len(w)):
if w[i] != 0:
if not first:
pde = pde + ' + '
pde = pde + "(%05f %+05fi)" % (w[i].real, w[i].imag) + rhs_description[i] + "\n "
first = False
print pde
##################################################################################
##################################################################################
#
# Functions for sparse regression.
#
##################################################################################
##################################################################################
def TrainSTRidge(R, Ut, lam, d_tol, maxit = 25, STR_iters = 10, l0_penalty = None, normalize = 2, split = 0.8, print_best_tol = False):
"""
This function trains a predictor using STRidge.
It runs over different values of tolerance and trains predictors on a training set, then evaluates them
using a loss function on a holdout set.
"""
# Split data into 80% training and 20% test, then search for the best tolderance.
np.random.seed(0) # for consistancy
n,_ = R.shape
train = np.random.choice(n, int(n*split), replace = False)
test = [i for i in np.arange(n) if i not in train]
TrainR = R[train,:]
TestR = R[test,:]
TrainY = Ut[train,:]
TestY = Ut[test,:]
D = TrainR.shape[1]
# Set up the initial tolerance and l0 penalty
d_tol = float(d_tol)
tol = d_tol
if l0_penalty == None: l0_penalty = 0.001*np.linalg.cond(R)
# Get the standard least squares estimator
w = np.zeros((D,1))
w_best = np.linalg.lstsq(TrainR, TrainY)[0]
err_best = np.linalg.norm(TestY - TestR.dot(w_best), 2) + l0_penalty*np.count_nonzero(w_best)
tol_best = 0
# Now increase tolerance until test performance decreases
for iter in range(maxit):
# Get a set of coefficients and error
w = STRidge(R,Ut,lam,STR_iters,tol,normalize = normalize)
err = np.linalg.norm(TestY - TestR.dot(w), 2) + l0_penalty*np.count_nonzero(w)
# Has the accuracy improved?
if err <= err_best:
err_best = err
w_best = w
tol_best = tol
tol = tol + d_tol
else:
tol = max([0,tol - 2*d_tol])
d_tol = 2*d_tol / (maxit - iter)
tol = tol + d_tol
if print_best_tol: print "Optimal tolerance:", tol_best
return w_best
def Lasso(X0, Y, lam, w = np.array([0]), maxit = 100, normalize = 2):
"""
Uses accelerated proximal gradient (FISTA) to solve Lasso
argmin (1/2)*||Xw-Y||_2^2 + lam||w||_1
"""
# Obtain size of X
n,d = X0.shape
X = np.zeros((n,d), dtype=np.complex64)
Y = Y.reshape(n,1)
# Create w if none is given
if w.size != d:
w = np.zeros((d,1), dtype=np.complex64)
w_old = np.zeros((d,1), dtype=np.complex64)
# Initialize a few other parameters
converge = 0
objective = np.zeros((maxit,1))
# First normalize data
if normalize != 0:
Mreg = np.zeros((d,1))
for i in range(0,d):
Mreg[i] = 1.0/(np.linalg.norm(X0[:,i],normalize))
X[:,i] = Mreg[i]*X0[:,i]
else: X = X0
# Lipschitz constant of gradient of smooth part of loss function
L = np.linalg.norm(X.T.dot(X),2)
# Now loop until converged or max iterations
for iters in range(0, maxit):
# Update w
z = w + iters/float(iters+1)*(w - w_old)
w_old = w
z = z - X.T.dot(X.dot(z)-Y)/L
for j in range(d): w[j] = np.multiply(np.sign(z[j]), np.max([abs(z[j])-lam/L,0]))
# Could put in some sort of break condition based on convergence here.
# Now that we have the sparsity pattern, used least squares.
biginds = np.where(w != 0)[0]
if biginds != []: w[biginds] = np.linalg.lstsq(X[:, biginds],Y)[0]
# Finally, reverse the regularization so as to be able to use with raw data
if normalize != 0: return np.multiply(Mreg,w)
else: return w
def ElasticNet(X0, Y, lam1, lam2, w = np.array([0]), maxit = 100, normalize = 2):
"""
Uses accelerated proximal gradient (FISTA) to solve elastic net
argmin (1/2)*||Xw-Y||_2^2 + lam_1||w||_1 + (1/2)*lam_2||w||_2^2
"""
# Obtain size of X
n,d = X0.shape
X = np.zeros((n,d), dtype=np.complex64)
Y = Y.reshape(n,1)
# Create w if none is given
if w.size != d:
w = np.zeros((d,1), dtype=np.complex64)
w_old = np.zeros((d,1), dtype=np.complex64)
# Initialize a few other parameters
converge = 0
objective = np.zeros((maxit,1))
# First normalize data
if normalize != 0:
Mreg = np.zeros((d,1))
for i in range(0,d):
Mreg[i] = 1.0/(np.linalg.norm(X0[:,i],normalize))
X[:,i] = Mreg[i]*X0[:,i]
else: X = X0
# Lipschitz constant of gradient of smooth part of loss function
L = np.linalg.norm(X.T.dot(X),2) + lam2
# Now loop until converged or max iterations
for iters in range(0, maxit):
# Update w
z = w + iters/float(iters+1)*(w - w_old)
w_old = w
z = z - (lam2*z + X.T.dot(X.dot(z)-Y))/L
for j in range(d): w[j] = np.multiply(np.sign(z[j]), np.max([abs(z[j])-lam1/L,0]))
# Could put in some sort of break condition based on convergence here.
# Now that we have the sparsity pattern, used least squares.
biginds = np.where(w != 0)[0]
if biginds != []: w[biginds] = np.linalg.lstsq(X[:, biginds],Y)[0]
# Finally, reverse the regularization so as to be able to use with raw data
if normalize != 0: return np.multiply(Mreg,w)
else: return w
def STRidge(X0, y, lam, maxit, tol, normalize = 2, print_results = False):
"""
Sequential Threshold Ridge Regression algorithm for finding (hopefully) sparse
approximation to X^{-1}y. The idea is that this may do better with correlated observables.
This assumes y is only one column
"""
n,d = X0.shape
X = np.zeros((n,d), dtype=np.complex64)
# First normalize data
if normalize != 0:
Mreg = np.zeros((d,1))
for i in range(0,d):
Mreg[i] = 1.0/(np.linalg.norm(X0[:,i],normalize))
X[:,i] = Mreg[i]*X0[:,i]
else: X = X0
# Get the standard ridge esitmate
if lam != 0: w = np.linalg.lstsq(X.T.dot(X) + lam*np.eye(d),X.T.dot(y))[0]
else: w = np.linalg.lstsq(X,y)[0]
num_relevant = d
biginds = np.where( abs(w) > tol)[0]
# Threshold and continue
for j in range(maxit):
# Figure out which items to cut out
smallinds = np.where( abs(w) < tol)[0]
new_biginds = [i for i in range(d) if i not in smallinds]
# If nothing changes then stop
if num_relevant == len(new_biginds): break
else: num_relevant = len(new_biginds)
# Also make sure we didn't just lose all the coefficients
if len(new_biginds) == 0:
if j == 0:
#if print_results: print "Tolerance too high - all coefficients set below tolerance"
return w
else: break
biginds = new_biginds
# Otherwise get a new guess
w[smallinds] = 0
if lam != 0: w[biginds] = np.linalg.lstsq(X[:, biginds].T.dot(X[:, biginds]) + lam*np.eye(len(biginds)),X[:, biginds].T.dot(y))[0]
else: w[biginds] = np.linalg.lstsq(X[:, biginds],y)[0]
# Now that we have the sparsity pattern, use standard least squares to get w
if biginds != []: w[biginds] = np.linalg.lstsq(X[:, biginds],y)[0]
if normalize != 0: return np.multiply(Mreg,w)
else: return w
def FoBaGreedy(X, y, epsilon = 0.1, maxit_f = 100, maxit_b = 5, backwards_freq = 5):
"""
Forward-Backward greedy algorithm for sparse regression.
See Zhang, Tom. 'Adaptive Forward-Backward Greedy Algorithm for Sparse Learning with Linear
Models', NIPS, 2008
"""
n,d = X.shape
F = {}
F[0] = set()
w = {}
w[0] = np.zeros((d,1), dtype=np.complex64)
k = 0
delta = {}
for forward_iter in range(maxit_f):
k = k+1
# forward step
non_zeros = np.where(w[k-1] == 0)[0]
err_after_addition = []
residual = y - X.dot(w[k-1])
for i in range(len(non_zeros)):
alpha = X[:,i].T.dot(residual)/np.linalg.norm(X[:,i])**2
w_added = np.copy(w[k-1])
w_added[i] = alpha
err_after_addition.append(np.linalg.norm(X.dot(w_added)-y))
i = np.argmin(err_after_addition)
F[k] = F[k-1].union({i})
w[k] = np.zeros((d,1), dtype=np.complex64)
w[k][list(F[k])] = np.linalg.lstsq(X[:, list(F[k])], y)[0]
# check for break condition
delta[k] = np.linalg.norm(X.dot(w[k-1]) - y) - np.linalg.norm(X.dot(w[k]) - y)
if delta[k] < epsilon: return w[k-1]
# backward step, do once every few forward steps
if forward_iter % backwards_freq == 0 and forward_iter > 0:
for backward_iter in range(maxit_b):
non_zeros = np.where(w[k] != 0)
err_after_simplification = []
for j in range(len(non_zeros)):
w_simple = np.copy(w[k])
w_simple[j] = 0
err_after_simplification.append(np.linalg.norm(X.dot(w_simple) - y))
j = np.argmin(err_after_simplification)
w_simple = np.copy(w[k])
w_simple[j] = 0
# check for break condition on backward step
delta_p = err_after_simplification[j] - np.linalg.norm(X.dot(w[k]) - y)
if delta_p > 0.5*delta[k]: break
k = k-1;
F[k] = F[k+1].difference({j})
w[k] = np.zeros((d,1), dtype=np.complex64)
w[k][list(F[k])] = np.linalg.lstsq(X[:, list(F[k])], y)[0]
return w[k]