def test_shift(cshift, dist, tshift): print 'test shift of',cshift,':', nnodes = [p + cshift for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in xrange(len(nodes))]) print ndist if ndist < dist: tshift = cshift dist = ndist return dist, tshift
def test_shift(cshift, dist, tshift): print('test shift of', cshift, ':', end=' ') nnodes = [p + cshift for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in range(len(nodes))]) print(ndist) if ndist < dist: tshift = cshift dist = ndist return dist, tshift
def check_rot_angle(crotangle, dist, tangle): print 'test rotation of',degrees(crotangle),':', m = pgl.Matrix3.axisRotation(p_edir[0],crotangle) nnodes = [m*p for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in xrange(len(nodes))]) print ndist if ndist < dist: tangle = crotangle dist = ndist return dist, tangle
def check_rot_angle(crotangle, dist, tangle): print('test rotation of', degrees(crotangle), ':', end=' ') m = pgl.Matrix3.axisRotation(p_edir[0], crotangle) nnodes = [m * p for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in range(len(nodes))]) print(ndist) if ndist < dist: tangle = crotangle dist = ndist return dist, tangle
def optimizeAlignementOrientation(points, mtg, p_edir=None): from .mtgmanip import mtg2pgltree import openalea.plantgl.all as pgl from .pointprocessing import np_inertia_axis from math import pi, degrees nodes, parents, vertex2node = mtg2pgltree(mtg) dist = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in range(len(nodes))]) print(dist) if p_edir is None: p_eval, p_edir, p_center = np_inertia_axis(points) nbtest = 72 rotangle = 2 * pi / nbtest tangle = 0 def check_rot_angle(crotangle, dist, tangle): print('test rotation of', degrees(crotangle), ':', end=' ') m = pgl.Matrix3.axisRotation(p_edir[0], crotangle) nnodes = [m * p for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in range(len(nodes))]) print(ndist) if ndist < dist: tangle = crotangle dist = ndist return dist, tangle for i in range(1, nbtest): crotangle = rotangle * i dist, tangle = check_rot_angle(crotangle, dist, tangle) nbtest = 10 rotangle = 2 * rotangle / nbtest gtangle = tangle for i in range(1, nbtest / 2): crotangle = gtangle - rotangle * i dist, tangle = check_rot_angle(crotangle, dist, tangle) for i in range(1, nbtest / 2): crotangle = gtangle + rotangle * i dist, tangle = check_rot_angle(crotangle, dist, tangle) if tangle != 0: print('select', degrees(tangle), dist) npos = dict() m = pgl.Matrix3.axisRotation(p_edir[0], tangle) for vid, pos in list(mtg.property('position').items()): npos[vid] = m * pos mtg.property('position').update(npos)
def optimizeAlignementOrientation(points, mtg, p_edir = None): from mtgmanip import mtg2pgltree import openalea.plantgl.all as pgl from pointprocessing import np_inertia_axis from math import pi, degrees nodes, parents, vertex2node = mtg2pgltree(mtg) dist = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in xrange(len(nodes))]) print dist if p_edir is None: p_eval, p_edir, p_center = np_inertia_axis(points) nbtest = 72 rotangle = 2*pi/nbtest tangle = 0 def check_rot_angle(crotangle, dist, tangle): print 'test rotation of',degrees(crotangle),':', m = pgl.Matrix3.axisRotation(p_edir[0],crotangle) nnodes = [m*p for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in xrange(len(nodes))]) print ndist if ndist < dist: tangle = crotangle dist = ndist return dist, tangle for i in xrange(1,nbtest): crotangle = rotangle*i dist, tangle = check_rot_angle(crotangle, dist, tangle) nbtest = 10 rotangle = 2 * rotangle / nbtest gtangle = tangle for i in xrange(1,nbtest/2): crotangle = gtangle - rotangle*i dist, tangle = check_rot_angle(crotangle, dist, tangle) for i in xrange(1,nbtest/2): crotangle = gtangle + rotangle*i dist, tangle = check_rot_angle(crotangle, dist, tangle) if tangle != 0: print 'select', degrees(tangle), dist npos = dict() m = pgl.Matrix3.axisRotation(p_edir[0],tangle) for vid, pos in mtg.property('position').items(): npos[vid] = m * pos mtg.property('position').update(npos)
def optimizeAlignementPosition(points, mtg, distanceratio=10, nbtests=10, p_edir=None): from .mtgmanip import mtg2pgltree import openalea.plantgl.all as pgl from .pointprocessing import np_inertia_axis from math import pi, degrees nodes, parents, vertex2node = mtg2pgltree(mtg) dist = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in range(len(nodes))]) print(dist) if p_edir is None: p_eval, p_edir, p_center = np_inertia_axis(points) mtgextent = pgl.Point3Array(list( mtg.property('position').values())).getExtent() def test_shift(cshift, dist, tshift): print('test shift of', cshift, ':', end=' ') nnodes = [p + cshift for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in range(len(nodes))]) print(ndist) if ndist < dist: tshift = cshift dist = ndist return dist, tshift for i in range(3): tshift = None unitshift = mtgextent[i] * distanceratio / 1000. for t in range(1, nbtests): cshift = p_edir[i] * t * unitshift dist, tshift = test_shift(cshift, dist, tshift) for t in range(1, nbtests): cshift = -p_edir[i] * t * unitshift dist, tshift = test_shift(cshift, dist, tshift) if not tshift is None: print('select', tshift, dist) npos = dict() for vid, pos in list(mtg.property('position').items()): npos[vid] = pos + tshift mtg.property('position').update(npos)
def optimizeAlignementPosition(points, mtg, distanceratio = 10, nbtests = 10, p_edir = None): from mtgmanip import mtg2pgltree import openalea.plantgl.all as pgl from pointprocessing import np_inertia_axis from math import pi, degrees nodes, parents, vertex2node = mtg2pgltree(mtg) dist = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in xrange(len(nodes))]) print dist if p_edir is None: p_eval, p_edir, p_center = np_inertia_axis(points) mtgextent = pgl.Point3Array(mtg.property('position').values()).getExtent() def test_shift(cshift, dist, tshift): print 'test shift of',cshift,':', nnodes = [p + cshift for p in nodes] ndist = pgl.average_distance_to_shape(points, nnodes, parents, [0 for j in xrange(len(nodes))]) print ndist if ndist < dist: tshift = cshift dist = ndist return dist, tshift for i in xrange(3): tshift = None unitshift = mtgextent[i] * distanceratio / 1000. for t in xrange(1, nbtests): cshift = p_edir[i]*t*unitshift dist, tshift = test_shift(cshift, dist, tshift) for t in xrange(1, nbtests): cshift = -p_edir[i]*t*unitshift dist, tshift = test_shift(cshift, dist, tshift) if not tshift is None: print 'select', tshift, dist npos = dict() for vid, pos in mtg.property('position').items(): npos[vid] = pos + tshift mtg.property('position').update(npos)
def alignGlobally(points, mtg, verbose = False): import openalea.plantgl.all as pgl import numpy as np from pointprocessing import np_inertia_axis mtgpoints = pgl.Point3Array(mtg.property('position').values()) axispoints = np_inertia_axis(points, verbose=verbose) axismtg = np_inertia_axis(mtgpoints, verbose=verbose) p_eval, p_edir, p_center = axispoints m_eval, m_edir, m_center = axismtg pointextent = pgl.norm(points.getExtent()) mtgextent = pgl.norm(mtgpoints.getExtent()) scaleratio = mtgextent / pointextent from math import log scale = 1./pow(10, round(log(scaleratio,10))) normalizeorientation = True checkorientation = True if normalizeorientation: def normalize_frame(edir): a, b = edir[0], edir[1] c = np.cross(a,b) return np.array([a, np.cross(c,a), c]) p_edir = normalize_frame(p_edir) m_edir = normalize_frame(m_edir) if verbose: print 'Point center :', p_center print 'MTG center :', m_center print 'Point axis :',p_edir print 'MTG axis :',m_edir print 'Point variance :',p_eval print 'MTG variance :',m_eval def transform(v,t_edir): v = (v - m_center) nval = [ pgl.dot(v,ed) for ed in m_edir] nv = sum([val * ed for val, ed in zip(nval, t_edir)],pgl.Vector3(0,0,0)) return (nv + p_center) ppos = mtg.property('position').copy() npos1 = dict([(vid, transform(pos, p_edir)) for vid, pos in ppos.items()]) #npos1 = dict([(vid, pos*scale) for vid, pos in ppos.items()]) mtg.property('position').update(npos1) if checkorientation: if verbose: print 'check orientation' from mtgmanip import mtg2pgltree nodes, parents, vertex2node = mtg2pgltree(mtg) dist1 = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in xrange(len(nodes))]) if verbose: print 'check flipped orientation' p_edir2 = np.array([-p_edir[0], -p_edir[1], np.cross(-p_edir[0], -p_edir[1])]) npos2 = dict([(vid, transform(pos, p_edir2)) for vid, pos in ppos.items()]) mtg.property('position').update(npos2) nodes, parents, vertex2node = mtg2pgltree(mtg) dist2 = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in xrange(len(nodes))]) if verbose: print dist1, dist2 if dist1 < dist2: if verbose: print 'Use first orientation' mtg.property('position').update(npos1) else: if verbose: print 'Use flipped orientation'
def alignGlobally(points, mtg, verbose=False): import openalea.plantgl.all as pgl import numpy as np from .pointprocessing import np_inertia_axis mtgpoints = pgl.Point3Array(list(mtg.property('position').values())) axispoints = np_inertia_axis(points, verbose=verbose) axismtg = np_inertia_axis(mtgpoints, verbose=verbose) p_eval, p_edir, p_center = axispoints m_eval, m_edir, m_center = axismtg pointextent = pgl.norm(points.getExtent()) mtgextent = pgl.norm(mtgpoints.getExtent()) scaleratio = mtgextent / pointextent from math import log scale = 1. / pow(10, round(log(scaleratio, 10))) normalizeorientation = True checkorientation = True if normalizeorientation: def normalize_frame(edir): a, b = edir[0], edir[1] c = np.cross(a, b) return np.array([a, np.cross(c, a), c]) p_edir = normalize_frame(p_edir) m_edir = normalize_frame(m_edir) if verbose: print('Point center :', p_center) print('MTG center :', m_center) print('Point axis :', p_edir) print('MTG axis :', m_edir) print('Point variance :', p_eval) print('MTG variance :', m_eval) def transform(v, t_edir): v = (v - m_center) nval = [pgl.dot(v, ed) for ed in m_edir] nv = sum([val * ed for val, ed in zip(nval, t_edir)], pgl.Vector3(0, 0, 0)) return (nv + p_center) ppos = mtg.property('position').copy() npos1 = dict([(vid, transform(pos, p_edir)) for vid, pos in list(ppos.items())]) #npos1 = dict([(vid, pos*scale) for vid, pos in ppos.items()]) mtg.property('position').update(npos1) if checkorientation: if verbose: print('check orientation') from .mtgmanip import mtg2pgltree nodes, parents, vertex2node = mtg2pgltree(mtg) dist1 = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in range(len(nodes))]) if verbose: print('check flipped orientation') p_edir2 = np.array( [-p_edir[0], -p_edir[1], np.cross(-p_edir[0], -p_edir[1])]) npos2 = dict([(vid, transform(pos, p_edir2)) for vid, pos in list(ppos.items())]) mtg.property('position').update(npos2) nodes, parents, vertex2node = mtg2pgltree(mtg) dist2 = pgl.average_distance_to_shape(points, nodes, parents, [0 for i in range(len(nodes))]) if verbose: print(dist1, dist2) if dist1 < dist2: if verbose: print('Use first orientation') mtg.property('position').update(npos1) else: if verbose: print('Use flipped orientation')