#######################data############################ p1 = 3 p2 = 3 # spline degree ne1 = 16 # number of elements ne2 = 16 print('~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~') print('Simulation with Ncells :=', '[', ne1, 'X', ne2, ']', ' Spline degree =', p1) print( '---------------------------------------------------------------------------' ) grid1 = linspace(-1, 1., ne1 + 1) grid2 = linspace(-1, 1., ne1 + 1) knots1 = make_knots(grid1, p1, periodic=False) knots2 = make_knots(grid2, p2, periodic=False) spans1 = elements_spans(knots1, p1) spans2 = elements_spans(knots2, p2) ###################################################### nelements1 = len(grid1) - 1 nelements2 = len(grid2) - 1 nbasis1 = len(knots1) - p1 - 1 nbasis2 = len(knots2) - p2 - 1 # we need the value a B-Spline and its first derivative nderiv = 1 # create the gauss-legendre rule, on [-1, 1] u1, w1 = gauss_legendre(p1)
#alpha=[-0.1,0.058] #grid=newgrid(grid1,alpha) #-------------------------------------------- #grid=np.array([-1. , -0.876,-0.69, -0.685,-0.31, -0.305, -0.064, 0.35 ,0.351, 0.64, 1. ]) #grid=np.array([-1. , -0.8997,-0.79992, -0.3306,-0.2002, -0.10001, -0.005, 0.1003 ,0.199, 0.8503, 1. ]) grid=np.array([-1. , -0.9097,-0.8002, -0.3306,-0.2002, -0.10001, 0.0, 0.1003 ,0.200, 0.8503, 1. ]) #grid=np.array([-1. , -0.986,-0.895, -0.775,-0.431, -0.4001, -0.164, 0.235 ,0.251, 0.54, 1. ]) #-------------------------------------------------- # ===========================uniform subdivision=============================== #---------------------------------------------- #grid = linspace(-1., 1., ne+1) #----------------------------------------------- # ========================================================== knots = make_knots(grid, p, periodic=False) spans = elements_spans(knots, p) nelements = len(grid) - 1 nbasis = len(knots) - p - 1 # we need the value a B-Spline and its first derivative nderiv = 1 # create the gauss-legendre rule, on [-1, 1] u, w = gauss_legendre( p ) # for each element on the grid, we create a local quadrature grid points, weights = quadrature_grid( grid, u, w ) # for each element and a quadrature points, # we compute the non-vanishing B-Splines