made the get_phis and qlinear functions work independant of dimension
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@ -7,7 +7,11 @@ from interp.tools import log
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def get_phis(X, R):
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"""
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The get_phis function is used to get barycentric coordonites for a point on a triangle.
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The get_phis function is used to get barycentric coordonites for a point on
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a triangle or tetrahedron:
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in 2D:
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X -- the destination point (2D)
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X = [0,0]
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@ -15,31 +19,9 @@ def get_phis(X, R):
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r = [[-1, -1], [0, 2], [1, -1]]
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this will return [0.333, 0.333, 0.333]
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"""
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# baker: eq 7
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A = np.array([
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[ 1, 1, 1],
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[R[0][0], R[1][0], R[2][0]],
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[R[0][1], R[1][1], R[2][1]],
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])
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b = np.array([ 1,
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X[0],
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X[1]
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])
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try:
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phi = np.linalg.solve(A,b)
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except np.linalg.LinAlgError as e:
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msg = "calculation of phis yielded a linearly dependant system (%s)" % e
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log.error(msg)
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raise Exception(msg)
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phi = np.dot(np.linalg.pinv(A), b)
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return phi
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def get_phis_3D(X, R):
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"""
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The get_phis function is used to get barycentric coordonites for a point on a tetrahedron.
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in 3D:
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X -- the destination point (3D)
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X = [0,0,0]
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@ -51,10 +33,22 @@ def get_phis_3D(X, R):
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[-0.47140452166803298, -0.81649658244673584, -0.3333333283722672],
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]
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this (should) will return [0.25, 0.25, 0.25, 0.25]
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this will return [0.25, 0.25, 0.25, 0.25]
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"""
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# baker: eq 7
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# TODO: perhaps also test R .. ?
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if len(X) == 2:
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A = np.array([
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[ 1, 1, 1],
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[R[0][0], R[1][0], R[2][0]],
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[R[0][1], R[1][1], R[2][1]],
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])
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b = np.array([ 1,
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X[0],
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X[1]
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])
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elif len(X) == 3:
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A = np.array([
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[ 1, 1, 1, 1 ],
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[R[0][0], R[1][0], R[2][0], R[3][0]],
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@ -66,15 +60,19 @@ def get_phis_3D(X, R):
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X[1],
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X[2]
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])
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else:
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raise Exception("inapropriate demension on X")
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try:
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phi = np.linalg.solve(A,b)
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except np.linalg.LinAlgError as e:
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log.error("calculation of phis yielded a linearly dependant system: %s" % e)
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msg = "calculation of phis yielded a linearly dependant system (%s)" % e
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log.error(msg)
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raise Exception(msg)
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phi = np.dot(np.linalg.pinv(A), b)
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return phi
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def qlinear(X, R):
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"""
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this calculates the linear portion of q from X to R
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@ -90,18 +88,7 @@ def qlinear(X, R):
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qlin = np.sum([q_i * phi_i for q_i, phi_i in zip(R.q, phis)])
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return phis, qlin
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def qlinear_3D(X, R):
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"""
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this calculates the linear portion of q from X to R
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X = destination point
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R = simplex points
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q = CFD quantities of interest at the simplex points(R)
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"""
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phis = get_phis_3D(X, R.verts)
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qlin = sum([q_i * phi_i for q_i, phi_i in zip(R.q, phis)])
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return phis, qlin
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qlinear_3D = qlinear
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def get_error(phi, R, S, order = 2):
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log.debug("len(phi): %d"% len(phi))
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@ -337,6 +337,7 @@ class delaunay_grid(grid):
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"""
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log.debug('start')
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qdelaunay_string = get_qdelaunay_dump_str(self)
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# log.debug(qdelaunay_string)
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cell_to_cells = []
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for matcher in delaunay_grid.cell_re.finditer(qdelaunay_string):
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d = matcher.groupdict()
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@ -355,9 +356,11 @@ class delaunay_grid(grid):
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nghbrs = [(cell_name, i) for i in neighboring_cells.split()]
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cell_to_cells.extend(nghbrs)
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log.debug(cell_to_cells)
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for rel in cell_to_cells:
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if rel[1] in self.cells:
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self.cells[rel[0]].add_neighbor(self.cells[rel[1]])
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log.debug(self.cells)
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log.debug('end')
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@ -1,4 +1,4 @@
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from interp.baker import get_phis, get_phis_3D
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from interp.baker import get_phis
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from interp.tools import log
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TOL = 1e-8
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@ -9,11 +9,10 @@ def contains(X, R):
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represented by a list of n-degree coordinates)
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it now correctly checks for 2/3-D verts
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TODO: write unit test ...
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"""
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if len(R) == 3:
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phis = get_phis(X, R)
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elif len(R) == 4:
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phis = get_phis_3D(X, R)
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r = True
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if [i for i in phis if i < 0.0 - TOL]:
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@ -1,7 +1,7 @@
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#!/usr/bin/env python
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import unittest
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from interp.baker import get_phis_3D, qlinear_3D
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from interp.baker import get_phis, qlinear
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from interp.grid import grid
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import numpy as np
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@ -19,16 +19,16 @@ class TestSequenceFunctions(unittest.TestCase):
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self.q = [0.0, 0.0, 0.0, 4]
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def testGetPhis3D(self):
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result = get_phis_3D(self.X, self.r)
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def testGetPhis(self):
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result = get_phis(self.X, self.r)
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right_answer = [0.25, 0.25, 0.25, 0.25]
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for a,b in zip(result, right_answer):
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self.assertAlmostEqual(a,b)
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def testQlinear3D(self):
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phi, result = qlinear_3D(self.X, grid(self.r, self.q))
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def testQlinear(self):
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phi, result = qlinear(self.X, grid(self.r, self.q))
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result = result
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right_answer = 1.0
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self.assertAlmostEqual(result, right_answer)
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