def get_interpolated_alglib(nx, ny, xc, yc, v,
nsample=16,
radius=100, nlayer=1, par=1.e0):
import xalglib
model = xalglib.rbfcreate(2, 1)
#xy = [[-1,0,2],[+1,0,3]]
#xy = np.array([xc, yc, v]).T
xy = map(list, zip(xc, yc, v))
xalglib.rbfsetpoints(model, xy)
#xalglib.rbfsetalgoqnn(model)
# check the meaning of par
xalglib.rbfsetalgomultilayer(model, radius, nlayer, par)
rep = xalglib.rbfbuildmodel(model)
tx = list(np.arange(0, nx, nsample)+nsample*.5)
ty = list(np.arange(0, ny, nsample)+nsample*.5)
#xti1 = xalglib.x_vector(512)
#xalglib.x_from_list(xti1, ti, xalglib.DT_REAL, xalglib.X_CREATE)
#xti2 = xalglib.x_vector(512)
#xalglib.x_from_list(xti2, ti, xalglib.DT_REAL, xalglib.X_CREATE)
vv1 = xalglib.rbfgridcalc2(model, tx, len(tx), ty, len(ty))
vv4 = ni.zoom(np.array(vv1).T, nsample)
return vv4
def get_interpolated_alglib(nx, ny, xc, yc, v,
nsample=16,
radius=100, nlayer=1, par=1.e0):
import xalglib
model = xalglib.rbfcreate(2, 1)
#xy = [[-1,0,2],[+1,0,3]]
#xy = np.array([xc, yc, v]).T
xy = map(list, zip(xc, yc, v))
xalglib.rbfsetpoints(model, xy)
#xalglib.rbfsetalgoqnn(model)
# check the meaning of par
xalglib.rbfsetalgomultilayer(model, radius, nlayer, par)
rep = xalglib.rbfbuildmodel(model)
tx = list(np.arange(0, nx, nsample)+nsample*.5)
ty = list(np.arange(0, ny, nsample)+nsample*.5)
#xti1 = xalglib.x_vector(512)
#xalglib.x_from_list(xti1, ti, xalglib.DT_REAL, xalglib.X_CREATE)
#xti2 = xalglib.x_vector(512)
#xalglib.x_from_list(xti2, ti, xalglib.DT_REAL, xalglib.X_CREATE)
vv1 = xalglib.rbfgridcalc2(model, tx, len(tx), ty, len(ty))
vv4 = ni.zoom(np.array(vv1).T, nsample)
return vv4
def create_spline_v2(x, y, z, rbase=5.0, nlayers=5, lambdaNS=0.0):
xy = np.zeros((x.shape[0], 3))
xy[:, 0] = x
xy[:, 1] = y
xy[:, 2] = z
xy = xy.tolist()
model = xal.rbfcreate(2, 1)
xal.rbfsetpoints(model, xy)
xal.rbfsetalgohierarchical(model, rbase, nlayers, lambdaNS)
xal.rbfbuildmodel(model)
return model
def _generate_rbf_potential(self, nstate, dimension, rbase, nlayers, lambdav):
#this function reads in the filename containing
#the 1 to 3-d data and generates a multilayer-rbf model
self.data = np.loadtxt(filename).tolist()
#initialize model
self.model = xa.rbfcreate(dimension,1)
xa.rbfsetpoints(self.model, self.data)
xa.rbfsetalgomultilayer(self.model, rbase, nlayers, lambdav)
self.potential = xa.rbfbuildmodel(self.model)
def RBFinterpolate(x, y, z, zIndex, gridData):
# ---- INTERPOLATION PARAMETERS ----
interpolationDimension = 2 # 2 for plane interpolation, 3 for volume interpolation
interpolationDataDimension = 1 # 1 for interplating scalar values, vector interpolation also possible
radiusFactorQ = 1.3 # default = 1.0, Coefficient for multiplying automatically determined interpolation radius, [0.75, 1.50], bigger factor gives greater smoothness
radiusMedianFactorZ = 5.0 # default = 5.0, each radius cannot be bigger than factorZ*median_radius, so it does not influences to many points
# ---- INTERPOLATION PARAMETERS END ----
# Printing info
name = mp.current_process().name
print ' ', name, 'interpolating plane number', zIndex + 1
xyz = np.vstack((x, y, z)).T # Arrange in matrix
xyzList = xyz.tolist() # Convert from array to normal list for xalglib
# Create interpolation object
plane = xl.rbfcreate(interpolationDimension, interpolationDataDimension)
xl.rbfsetpoints(plane, xyzList)
# Calculate weights
xl.rbfsetalgoqnn(plane, radiusFactorQ, radiusMedianFactorZ)
xl.rbfbuildmodel(plane)
xAxis = gridData[0]
xAxisLen = gridData[1]
yAxis = xAxis
yAxisLen = xAxisLen
interpolatedPlaneList = xl.rbfgridcalc2(plane, xAxis, xAxisLen, yAxis,
yAxisLen)
interpolatedPlane = np.asarray(interpolatedPlaneList,
dtype=np.float64) # Convert to numpy array
#interpolatedPlane = np.absolute(interpolatedPlane) # Absolute value of all datapoints
return [zIndex, interpolatedPlane]
# subset array xsub=slice(80,110) ysub=slice(80,110) velocsub=np.abs(np.copy(veloc[xsub,ysub])) # make vectors x,y=np.where(~np.isnan(velocsub)) z=velocsub[x,y] # create data array (need transpose) xyz=np.array([x,y,z],np.float).T xyz0=xyz.tolist() # creates 2D model (2) with scalar # function values (1) model = alg.rbfcreate(2, 1) # include obs into the model alg.rbfsetpoints(model, xyz0) # sets the model radius=5.0 nlayers=3 lamb=1.0e-3 alg.rbfsetalgomultilayer(model,radius,nlayers,lamb) # build the model and return a report rep = alg.rbfbuildmodel(model) xg=np.arange(velocsub.shape[0],dtype='float32') yg=np.arange(velocsub.shape[1],dtype='float32')
data_cart = np.loadtxt("./U_0allf_cart.dat",skiprows=2)
print "making spline... "
sz = np.max(np.size(data_cart[:,0]))
print sz
print data_cart
print len(data_cart[:,0].tolist())
splinefit = xalglib.spline3dbuildtrilinearv(data_cart[:,0].tolist(), sz,
data_cart[:,1].tolist(), sz,
data_cart[:,2].tolist(), sz,
data_cart[:,3].tolist(), 1)
print "...done"
else:
print "creating interpolant for cartesian data... "
data_cart = np.loadtxt("./U_0allf_cart.dat",skiprows=2)
# make an empty 3 dimensional scalar interpolation model
model_cart = xalglib.rbfcreate(3, 1)
xalglib.rbfsetpoints(model_cart, data_cart.tolist())
xalglib.rbfsetalgomultilayer(model_cart, 0.03, 4, 1.0e-3)
rep = xalglib.rbfbuildmodel(model_cart)
print " ...finished."
if integrateit:
data = np.loadtxt("./U_0allf_rad.dat",skiprows=2)
print "preview of data sampling... "
from mayavi import mlab
xs = data[:,0]*np.sin(data[:,1])*np.cos(data[:,2])
ys = data[:,0]*np.sin(data[:,1])*np.sin(data[:,2])
zs = data[:,0]*np.cos(data[:,1])
mlab.points3d(xs, ys, np.zeros(np.shape(xs)),mode='point')
# # # We have 2-dimensional space and very simple interpolation problem - all # points are distinct and located at straight line. We want to solve it # with RBF-ML algorithm. This problem is very simple, and RBF-QNN will # solve it too, but we want to evaluate RBF-ML and to start from the simple # problem. # X Y # -2 1 # -1 0 # 0 1 # +1 -1 # +2 1 # model = xalglib.rbfcreate(2, 1) xy0 = [[-2,0,1],[-1,0,0],[0,0,1],[+1,0,-1],[+2,0,1]] xalglib.rbfsetpoints(model, xy0) # First, we try to use R=5.0 with single layer (NLayers=1) and moderate amount # of regularization.... but results are disappointing: Model(x=0,y=0)=-0.02, # and we need 1.0 at (x,y)=(0,0). Why? # # Because first layer gives very smooth and imprecise approximation of the # function. Average distance between points is 1.0, and R=5.0 is too large # to give us flexible model. It can give smoothness, but can't give precision. # So we need more layers with smaller radii. xalglib.rbfsetalgomultilayer(model, 5.0, 1, 1.0e-3) rep = xalglib.rbfbuildmodelnp(model) print(rep.terminationtype) # expected 1 v = xalglib.rbfcalc2(model, 0.0, 0.0)
# -*- coding: utf-8 -*- # kate: indent-pasted-text false; indent-width 4; """ Test of RBF-ML algorithm (multilayer algorithm) """ import xalglib as xl model = xl.rbfcreate(2, 1) xy0 = [[-2,0,1],[-1,0,0],[0,0,1],[+1,0,-1],[+2,0,1]] xl.rbfsetpoints(model, xy0) xl.rbfsetalgomultilayer(model, 5.0, 4, 1.0e-3) rep = xl.rbfbuildmodel(model) xAxis = [-2.0, -1.5, -1.0, -0.5, 0.0, 0.5, 1.0, 1.5, 2.0] v = xl.rbfgridcalc2(model, xAxis, 9, [0.0], 1) print v
def __init__(self, indices ,datafiles, rbase, nlayers, lambdav, C_min=0.0001, C_max=0.55, C_chi=0.65, **kwargs):
ALGLIBCalculator.__init__(self,datafiles, rbase, nlayers, lambdav, **kwargs)
#construct energy potentials
self.model = []
zz = np.loadtxt(datafiles[0])
x = zz[:,0]
y = zz[:,1]
z = zz[:,2]
s0 = zz[:,3]
s1 = zz[:,4]
s2 = zz[:,5]
S0_min = s0.min()
x_max = x.max()
x_min = x.min()
y_max = y.max()
y_min = y.min()
z_max = z.max()
z_min = z.min()
data_s0 = np.column_stack([x,y,z,s0-S0_min]).tolist()
data_s1 = np.column_stack([x,y,z,s1-S0_min]).tolist()
data_s2 = np.column_stack([x,y,z,s2-S0_min]).tolist()
# RBF FITTING #
#Dimensionality of the space and of the function (scalar)
model_s0 = xa.rbfcreate(3,1)
model_s1 = xa.rbfcreate(3,1)
model_s2 = xa.rbfcreate(3,1)
#Set data
xa.rbfsetpoints(model_s0, data_s0)
xa.rbfsetpoints(model_s1, data_s1)
xa.rbfsetpoints(model_s2, data_s2)
#QNN set method and build model - q = 1.0, z = 5.0
#xa.rbfsetalgoqnn(model, 1.8, 5.0)
#Multilayer algorithm
#rbfsetalgomultilayer(model, rbase, nlayers, lambdav)
# lambda best from 0.001 to 0.1, 0.01 is default
xa.rbfsetalgomultilayer(model_s0, rbase, nlayers)#, lambdav)
xa.rbfsetalgomultilayer(model_s1, rbase, nlayers)#, lambdav)
xa.rbfsetalgomultilayer(model_s2, rbase, nlayers)#, lambdav)
rep_s0 = xa.rbfbuildmodel(model_s0)
rep_s1 = xa.rbfbuildmodel(model_s1)
rep_s2 = xa.rbfbuildmodel(model_s2)
self.model = [model_s0, model_s1, model_s2]
self.energy = None
self._forces = None
self._couplings = None
self.positions = None
self.current_state = None
if indices is None:
self.indices1 = [0,1,2,3]
else:
self.indices1 = indices
self.indices2 = [indices[2],indices[1],indices[0]]
self.indices3 = [indices[1],indices[2],indices[3]]
#DIABATIC COUPLING parameters
self.C_min = C_min
self.C_max = C_max
self.C_chi = C_chi