470 lines
23 KiB
Plaintext
470 lines
23 KiB
Plaintext
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# coding: utf-8
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============================================================
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| Empty_Spheres Modules |
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============================================================
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Made by : Ulysse DUPONT
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Collaboration with : Didier SEBILLEAU, Sylvain TRICOT
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Helped by : Floris Bruynooghe (Delny) and the team from scipy.spatial (qhull/Voronoi)
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Path : msspec/src/python/pymsspec/msspec/es
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Language : Python
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Important Global Variable : ES_AllRadius
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============================================================
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| About ES_AllRadius |
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============================================================
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For now : Empty spheres can be created from a cluster of Atoms.
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The missing part is the definition of the Empty-Sphere Python Class : they are considered as "X" Atoms.
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It means that the radius of empty spheres are not directly linked to them :
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The routine empty-spheres.Atom_Radius(Structure,n,list) will recognize empty spheres because their atom number is 0.
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So we created ES_AllRadius global variable, wich is updated after each EmptySphere generation with function
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"ES_AllRadius_Updater(NewES,Structure)". The new radius are calculated brutally by taking the max, without touching
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Structure molecules
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To use this global variable, it will be necessary to delete no empty spheres (or be sure to delete the
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correspondant radius in ES_AllRadius).
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An example of ES_AllRadius use is given afterward : in the example "Covering GeCl4 using ES_AllRadius"
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In the future, the informations about each empty-spheres radius can be taken directly in construction routines, and linked
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to the empty-sphere python object.
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============================================================
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| Objectives |
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============================================================
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The empty_spheres modules are routines made to add empty spheres in clusters for diffusion computations.
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The routines used are based on tetrahedralisation, convex-hull research and triangularisation to create adapted mesh,
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and uses tangent-spheres resolutions to compute adapted coordinates and radius of empty-spheres
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============================================================
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| How to use ? |
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============================================================
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Before adding empty-spheres, you need a cluster, or list of positions.
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The argument name "Structure" designs the Atoms type in pymsspec. The coordinates of the set of points is given
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by the command : numpy.ndarray.tolist(Structure.positions)
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For the moment, empty-sphere type isn't defined, only coordinates are computed.
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To see how the routines work : We will show few examples : You just need to adjust the folder where the xyz files will be
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__________________Internal/External ConvexHull Cover in C60_____________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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Structure = read('cluster_examples/C60.xyz')
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ExtCover = esph.Convex_Hull_Cover(Structure,radius_es=1,tol=1)
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1
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Result = Atoms(positions = ExtCover)
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view(Structure + Result)
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IntCover1 = esph.Internal_Hull_Cover(Structure,radius_es=0.84,tol=0.6)
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l=len(IntCover1)
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wcolor = "B"+str(l)
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Result1 = Atoms(wcolor,positions = IntCover1)
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view(Structure + Result1)
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IntCover2 = esph.Internal_Hull_Cover(Structure + Result1)
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Result2 = Atoms(positions = IntCover2)
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view(Result1 + Result2)
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view(Structure + Result1 + Result2)
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=================================Comments :
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The view will allow you to see the added spheres. For the moment, no empty spheres objects have been created,
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so we defin special radii, from covalent radii table.
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You can change IntCover1, for example taking radius_es = 0.71 and wcolor with "N" letter,
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or es_radius = 0.76 and C letter,etc... The letter allow view function to set correct radii.
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The tol parameter influences Fusion_Overlap. Spheres are fusionned if the distance beetween centers is less than
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the sum of the two spheres raddi, multiplied by tol parameter. So tol=1 is used to completely avoid spheres to touch
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themselves. Default value of tol has been subjectively settled at 0.6
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ICover2 will ask for radius_es : it is not given in the function call.
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If you put radius = 1.3, for example, you will obtain the centroid of the hull after fusionning the spheres.
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Try very big or smaller radius to understand how fusion works.
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____________________________________________________
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__________________Delaunay TetraHedral with a cube face-centered________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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struct = struct = [[0,-1,0],[0,1,0],[0,0,1],[0,0,-1],[1,0,0],[-1,0,0],[-1,-1,-1],[1,-1,-1],[-1,1,-1],[1,1,-1],[-1,-1,1],[1,-1,1],[-1,1,1],[1,1,1]]
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Structure = Atoms("C14",positions=struct)
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set1 = esph.Delaunay_Tetrahedral_ES(Structure)
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Set1 = Atoms (positions = set1)
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view(Set1)
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view(Structure + Set1)
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set2 = esph.Delaunay_Tetrahedral_ES(Structure+Set1)
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Set2 = Atoms (positions = set2)
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view(Set2)
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view(Structure + Set1 + Set2)
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=================================Comments :
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First iteration as you can see is given with np minsize and maxsize : This parameters are otionnaly set both at 0 and 999.
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The second iteration will show you an actual problem :
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The size of empty spheres must be saved to be used once more.
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If free space is to small, the routine will obtain some unsolvable problems. This issue is showed in your board with
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singular matrix
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____________________________________________________
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__________________Delaunay TetraHedral with a copper sample_____________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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Structure = read('cluster_examples/copper.xyz')
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set1 = esph.Delaunay_Tetrahedral_ES(Structure)
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Set1 = Atoms (positions = set1)
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view(Set1)
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view(Structure + Set1)
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=================================Comments :
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First iteration as you can see is given with np minsize and maxsize : This parameters are otionnaly set both at 0 and 999.
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If you want to delete the empty-spheres added out of convexhull, you can add the parameter maxsize=2
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No second iteration is done : see the centered cube example for explanations.
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____________________________________________________
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__________________Experiment problem of missing spheres in cover________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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struct = struct = [[0,-1,0],[0,1,0],[0,0,1],[0,0,-1],[1,0,0],[-1,0,0],[-1,-1,-1],[1,-1,-1],[-1,1,-1],[1,1,-1],[-1,-1,1],[1,-1,1],[-1,1,1],[1,1,1]]
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Structure = Atoms("C14",positions=struct)
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ExtCover = esph.Convex_Hull_Cover(Structure,radius_es=1,missing=True)
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1
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Result = Atoms(positions = ExtCover)
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view(Structure + Result)
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ExtCover = esph.Convex_Hull_Cover(Structure,radius_es=1)
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1
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Result = Atoms(positions = ExtCover)
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view(Structure + Result)
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=================================Comments :
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As you will see : The Second Result show only 6 empty spheres, and this spheres could maybe overlap the centers of facets.
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Classic ConveHull routine returns only boundary points of facets : if points are included in this facets, they miss...
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To solve this problem : put the optionnal parameter "missing" at "True". Do it when your cluster as some huge facets with
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some atoms included in (exactly like this cube facets, wich are centered).
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The first result shows the "good way" : it solves the problem of atoms forgotten by ConvexHull routine.
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____________________________________________________
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__________________Covering Nanotube_____________________________________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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Structure = read('cluster_examples/tubes.xyz')
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#set = np.ndarray.tolist(Structure.positions)
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#hull=ConvexHull(set)
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Cover = esph.Convex_Hull_Cover(Structure,radius_es=1,missing=True)
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Result = Atoms(positions = Cover)
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view(Structure + Result)
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=================================Comments :
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Computing time here is bigger, as you will see (Operation is done twice, if you need to go faster, you can do internal and
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external cover in one same routine, by not using Select_Int_Ext function.
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You can test routine with no missing parameter (missing=False by default) : You will feel good the problem of ConvexHull.
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____________________________________________________
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__________________Covering little NH3___________________________________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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Structure = read('cluster_examples/NH3.xyz')
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FCover = esph.Flat_Covering(Structure)
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1
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3
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Result = Atoms(positions = FCover)
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view(Structure + Result)
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Cover = esph.Convex_Hull_Cover(Structure)
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1
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Result = Atoms(positions = Cover)
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view(Structure + Result)
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TCover = esph.Delaunay_Tetrahedral_ES(Structure)
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Result = Atoms(positions = TCover)
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view(Structure + Result)
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=================================Comments :
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Using Flat Covening in caseof little molecule can let some problems : the "biggest plane" selected isn't H3, but an NH2
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face. The results you would prefer are obtained in Convex_Hull_Cover : with a small radius (1 for example), overlap will
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happen and routine computes only the empty sphere on the other side of H3 face. With bigger radius (try 2), you will
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obtain 3 empty spheres.
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TCover uses Tetrahedral resolution. But this problem set a radius solution of polygon with delta < 0, ie no solution is
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computed
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__________________Covering GeCl4 using ES_AllRadius global variable_____________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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Structure = read('cluster_examples/GeCl4.xyz')
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Cover = esph.Convex_Hull_Cover(Structure,radius_es=2)
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1
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Result = Atoms(positions = Cover)
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view(Structure+Result)
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ESAR1=esph.ES_AllRadius_Updater(Result,Structure,list=1)
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print("Actual ES radius list (ESAR1) :\n{}".format(ESAR1))
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Structure=Structure+Result
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Cover = esph.Convex_Hull_Cover(Structure,radius_es=3.5,tol=0)
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1
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Result = Atoms(positions = Cover)
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view(Structure+Result)
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ESAR2=esph.ES_AllRadius_Updater(Result,Structure,list=1)
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print("Actual ES radius list (ESAR2) :\n{}".format(ESAR2))
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comp1=ESAR2[-1]
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Cover = esph.Convex_Hull_Cover(Structure,radius_es=3.5)
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1
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Result = Atoms(positions = Cover)
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view(Structure+Result)
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ESAR2bis=esph.ES_AllRadius_Updater(Result,Structure,list=1)
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comp2=ESAR2bis[-1]
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print("\n\nWithout fusioning 2nd Cover, empty spheres are sized {} , after fusion there radius is {}".format(comp1,comp2))
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=================================Comments :
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ESAR1 and ESAR2 are just copy in time of the global variable "ES_AllRadius". Indeed : this global variable is used in
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empty_spheres.py, not in main. So ES_AllRadius_Updater returns the global variable in the time it is called.
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We also use this example to show tol use : in the second covering, we need a big radius to touch the 3 bounds of triangle
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vertices, so afterward the empty spheres are overlapping. So without tol parameter (tol=0.6 by default), the empty-spheres
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fusion, and the second cover is aligned with Cl atoms.
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With tol = 0 , no fusion is done, so we have more empty spheres in cover.
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Comparing the size of spheres with and without fusionning, you can see that fusion isn't always a good solution.
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__________________Covering molecule Phtalocyanine_______________________________________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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from scipy.spatial import ConvexHull
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Structure = read('cluster_examples/phtalocyanine.xyz')
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view(Structure)
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FCover = esph.Flat_Covering(Structure,R=2)
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Result = Atoms(positions = FCover)
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view(Structure + Result)
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FCover = esph.Flat_Covering(Structure,Curved=True)
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Result = Atoms(positions = FCover)
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view(Structure + Result)
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=================================Comments :
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The first FCover is using classic "FlatCovering" : the routine search for every plane, then triangulate and add ES.
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The problem here is that phtalocyanine is curved : so the polygons we see are not in same plane !
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As command : Enter 1 to tell there are a lot of different planes.
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To see the planes constructed, remove the R=2 parameter. Don't be afraid about time taken in this routine (5min possible)
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To solve the problem : we add the "Curved=True" : as the cluster is close to z=0 plane (but curved), we project him as
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2D plane with z=0. So we can triangulate correctly. Be careful with this method : all spheres are taken in the mesh !
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As radius, you should select 1.5, and do again with 2 : The results are pretty different because of the overlap : it can
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be interesting to compare the results.
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__________________Computin Voronoi Vertices of a Structure (face-centered cube)_________________________________________
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=================================Commands :
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from ase import Atoms
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from ase.io import write,read
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from ase.visualize import view
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from es_mod import empty_spheres as esph
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Structure = read('cluster_examples/centeredcube.xyz')
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Vor=esph.Voronoi_Vertex(Structure)
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Result=Atoms(positions=Vor)
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view(Structure+Result)
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Structure = read('cluster_examples/GeCl4.xyz')
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Vor=esph.Voronoi_Vertex(Structure)
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Result=Atoms(positions=Vor)
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view(Structure+Result)
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Structure = read('cluster_examples/tubes.xyz')
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Vor=esph.Voronoi_Vertex(Structure)
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Result=Atoms(positions=Vor)
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view(Structure)
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view(Structure+Result)
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=================================Commands for complete Voronoi informations (ridges, regions/polyhedrons) :
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from ase import Atoms
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from ase.io import write,read
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import numpy as np
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from scipy.spatial import Voronoi
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Structure = read('cluster_examples/centeredcube.xyz')
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Str=np.ndarray.tolist(Structure.positions)
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Vor = Voronoi(Str)
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Vor. [Then click on Tab]
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=================================Comments :
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The Voronoi_Vertex routine uses scipy.spatial.Voronoi :
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https://docs.scipy.org/doc/scipy-0.19.1/reference/generated/scipy.spatial.Voronoi.html
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You can use commands for complete Voronoi information to get voronoi ridges, regions, etc (see details after clicking Tab)
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As you can see, the Voronoi research is very similar to the research of empty spheres. But the common errors solved
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before will happen here to (see the 2 last figures : example with nanotube)
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Other Voronoi Tesselations can be found under C++ opensource Voro++ : http://math.lbl.gov/voro++/about.html
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========================================================================================================================
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========================================================================================================================
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============================================================
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| Routines |
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============================================================
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The Empty_Spheres routines are agenced in different folders :
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=====================empty_spheres.py=========================
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ES_AllRadius_Updater(NewES,Structure,[list]) : Update ES_AllRadius global variable with new radius of empty spheres
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given as NewES
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Voronoi_Vertex(Structure) : Computes Voronoi Vertices of Structure
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Delaunay_Tetrahedral_ES(Structure,[minsize],[maxsize],[tol]) : Creates a tetrehedral mesh from the structure,
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then returns for each center the perfect sphere going in.
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Convex_Hull_Cover(Structure,[es_radius],[tol],[missing],[Int_Ext]) : Finds the exterior Hull from the set, create triangular
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mesh then returns cover coordinates. tol=0 => no fusion
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Select_Int_Ext(Centroid,E1,E2,IE) : Clean the Cover, taking only internal or external
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Internal_Hull_Cover(Structure,[es_radius],[tol],[missing]) : Finds the interior Hull from the set, create triangular
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mesh then returns cover coordinates
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Internal_Hull_Centers(set) : Finds the interior Hull from the set, create triangular mesh then returns centers coordinates
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ES_Fusion(set, structure, size) : Change the set by clustering spheres near from size to each other. No size given => take shortest
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Maintain distances with structure, compared with the ancient set.
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Fusion_Overlap(Spheres_Data,tol) : Find Spheres touching each other, and fusions them. Don't return radius : only final coordinates
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Flat_Covering(Structure,[R],[tol],[Curved]) : For flat (or almost) set : Searchs major plane, triangulates,
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and cover the 2 sides.
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Plane_Triangulation(Plane3D,Plane_eq): Return triangulation of a 3D Plane (convert into 2D, uses Delny)
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Atom_Radius(Structure,n,list) : Returns radius of n°th atom in Structure (Angstrom). Regroup different radius lists.
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Convex_Hull_InterCover(set) : Return list of internal cover using ConvexHull : Different from Delaunay_Intersphere :
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made for empty clusters
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==============================================================
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=====================es_clustering.py=========================
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Tangent_Fourth_Sphere(Spheres_data, r, inout=1) : From 3 tangent spheres, returns the fourth, tangent to others, with radius r.
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inout determines the side of the coordinate.
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Spheres_Data_Structure_Extractor (Structure,list) : From Structure, returns data as [[S1][S2]...] where Si = [[xi,yi,zi],ri]
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used in Tangent_Fourth routine. List determines the radius we will use.
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Spheres_Data_XYZ_Extractor (name,list) : From name, given as "_____.xyz", returns data as [[S1][S2]...] where Si = [[xi,yi,zi],ri]
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used in Tangent_Fourth routine. List determines the radius we will use.
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Tetrahedron_ES (Spheres_data) : From 4 spheres forming a tetrahedron,returns the sphere tangent to others, with radius r.
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Triangle_ES (Spheres_data,R) : Returns the 2 solutions of tangent of 3 spheres with radius R.
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==============================================================
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========================es_tools.py===========================
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=================Vector tools==================
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vector_def(A,B) : returns simply the vector translating A to B
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vector_norm(V) : return euclidian norm of a vector
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throw_away (P,O,d) : returns P' so as O,P and P' are aligned, and OP'=d. So it translate P from O with distance d to direction OP
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angle_vector(u,v) : returns the value of the convex angle defined by vectors u and v, in radians.
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ColinearTest(u,v) : returns 1 if u and v colinear, and 0 if not.
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===========Distance and Proximity tools========
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distance(a,b) : calculate distance between 2 points
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search_nearest(point,set,d) : search the point in set wich is the nearest from point. We must know that the min distance is d
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point_set_proximity(point, set) : returns the min distance between the point and the set of points
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set_set_proximity(S1,S2) : returns minimal distance between each points of each sets.
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longest_dist(set) : returns the longest distance between the points in the set
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|
shortest_dist(set) : returns the shortest distance between the points in the set
|
||
|
dist_point_plan(Pt,Plan) : From Pt=[x,y,z] and Plan=[a,b,c,d], return distance beetween Pt and Plan
|
||
|
|
||
|
===============Construction tools===============
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|
Isobarycenter(set) : Calculate isobarycenter of a set of points. Returns his coordinates
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||
|
Invert_Coord(set,O,r) : Apply circular inversion to every point in the set, excepted for origin, remaining origin.
|
||
|
Midpoint(P1,P2) : Computes the middle point of P1 and P2
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||
|
rot3D(P,A,u) : Returns P' image of P by rotation from angle A around unity vector u
|
||
|
===================Data tools===================
|
||
|
commonlist(L1,L2) : Returns a list of elements common to L1 and L2, ie output is L1 intercection with L2
|
||
|
cleanlist(list) : Returns a list without repeated elements (each element in cleaned list appears only once)
|
||
|
=====================es_sym_analys.py=========================
|
||
|
sym_analyse(Cluster) : Convert set into xyz folder, then finds all symetries using. Uses compare_sym and read_sym_file
|
||
|
|
||
|
major_plane(set) : Search the major plane with max nb of points in set and returns all of his points, and his equation
|
||
|
|
||
|
Cluster_flatness_informations(set) : Returns set's hull's total volume and area
|
||
|
|
||
|
Cluster_search_hollow(set,tol) : Returns the hollow datas : hollow=[[list,center,volume]...] where list is hollow' vertice's
|
||
|
|
||
|
Cluster_emptyness_informations(structure) : Returns the % of volume of hull occupied by his spheres index,[center,volume] his hollow's center and volume. tol defines hollow's diagonale
|
||
|
|
||
|
Vertice_Sphere_Proportion(O,hull) : Returns the proportion of the sphere centered in Oth pt in the hull (proportion in ]O,1])
|
||
|
|
||
|
hull_search_neighbors(O,Simplices) : Returns list including O and neighbors (list contains only index, no coordinates)
|
||
|
|
||
|
convex_base(Neil,Simplices) : Returns all Neil[0] neighbors so as ConvBase is the base of pyramid from top Neil[0]
|
||
|
|
||
|
Neighbors_List(numAtom,Structure) : Returns index list in Structure of neighbors of Atom indexed numAtom. numatom not included
|
||
|
|
||
|
Hull_Tetracut(O,Structure,hull) : Returns index list in Structure of centers of spheres defining the terahedron cuting the vertice O
|
||
|
|
||
|
facet_cap(O,Structure,hull) : Return the proportion of sphere centered in O out from the hull(ie return the cap proportion of the sphere defined by cuting sphere with hull facets)
|
||
|
==============================================================
|
||
|
|
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