#! /usr/bin/env python # def rhs_lukas ( nu, rho, n, x, y, t ): #*****************************************************************************80 # ## RHS_LUKAS returns right hand sides of the Spiral Flow equations. # # Location: # # http://people.sc.fsu.edu/~jburkardt/py_src/navier_stokes_2d_exact/rhs_lukas.py # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 07 March 2015 # # Author: # # John Burkardt # # Parameters: # # Input, real NU, the kinematic viscosity. # # Input, real RHO, the density. # # Input, integer N, the number of points at which the solution is to # be evaluated. # # Input, real X(N), Y(N), the coordinates of the points. # # Input, real T(N), the time coordinate or coordinates. # # Output, real F(N), G(N), H(N), the right hand sides in the U, V and P equations. # import numpy as np f = np.zeros ( n ) g = np.zeros ( n ) h = np.zeros ( n ) u = - np.cos ( np.pi * x ) / np.pi dudt = np.zeros ( n ) dudx = np.sin ( np.pi * x ) dudxx = np.pi * np.cos ( np.pi * x ) dudy = np.zeros ( n ) dudyy = np.zeros ( n ) v = - y * np.sin ( np.pi * x ) dvdt = np.zeros ( n ) dvdx = - np.pi * y * np.cos ( np.pi * x ) dvdxx = + np.pi * np.pi * y * np.sin ( np.pi * x ) dvdy = - np.sin ( np.pi * x ) dvdyy = np.zeros ( n ) p = np.zeros ( n ) dpdx = np.zeros ( n ) dpdy = np.zeros ( n ) f = dudt - nu * ( dudxx + dudyy ) + u * dudx + v * dudy + dpdx / rho g = dvdt - nu * ( dvdxx + dvdyy ) + u * dvdx + v * dvdy + dpdy / rho h = dudx + dvdy return f, g, h def rhs_lukas_test ( ): #*****************************************************************************80 # ## RHS_LUKAS_TEST samples the right hand sides at the initial time. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 07 March 2015 # # Author: # # John Burkardt # import numpy as np import platform from r8vec_uniform_ab import r8vec_uniform_ab nu = 1.0 rho = 1.0 print ( '' ) print ( 'RHS_LUKAS_TEST' ) print ( ' Python version: %s' % ( platform.python_version ( ) ) ) print ( ' Lukas Bystricky Flow' ) print ( ' Sample the Navier-Stokes right hand sides' ) print ( ' at the initial time T = 0, over the unit square.' ) print ( ' Kinematic viscosity NU = %g' % ( nu ) ) print ( ' Fluid density RHO = %g' % ( rho ) ) n = 1000 r8_lo = 0.0 r8_hi = 1.0 seed = 123456789 x, seed = r8vec_uniform_ab ( n, r8_lo, r8_hi, seed ) y, seed = r8vec_uniform_ab ( n, r8_lo, r8_hi, seed ) t = 0.0 f, g, h = rhs_lukas ( nu, rho, n, x, y, t ) print ( '' ) print ( ' Minimum Maximum' ) print ( '' ) print ( ' Ur: %14.6g %14.6g' % ( np.min ( f ), np.max ( f ) ) ) print ( ' Vr: %14.6g %14.6g' % ( np.min ( g ), np.max ( g ) ) ) print ( ' Pr: %14.6g %14.6g' % ( np.min ( h ), np.max ( h ) ) ) # # Terminate. # print ( '' ) print ( 'RHS_LUKAS_TEST:' ) print ( ' Normal end of execution.' ) return if ( __name__ == '__main__' ): from timestamp import timestamp timestamp ( ) rhs_lukas_test ( ) timestamp ( )