#! /usr/bin/env python # def smith1_b ( m ): #*****************************************************************************80 # ## SMITH1_B returns the bounds in the smith1 problem. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 06 December 2016 # # Author: # # John Burkardt # # Reference: # # Reference: # # Andrew Smith, # Fast construction of constant bound functions for sparse polynomials, # Journal of Global Optimization, # Volume 43, 2009, pages 445-458. # # Parameters: # # Input, integer M, the number of variables. # # Output, integer L(M), U(M), the lower and upper bounds. # import numpy as np l = np.array ( [ +1.0, +2.0, +4.0, -5.0, +2.0 ] ) u = np.array ( [ +2.0, +3.0, +6.0, -2.0, +10.0 ] ) return l, u def smith1_f ( m, n, x ): #*****************************************************************************80 # ## SMITH1_F returns the function in the smith1 problem. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 06 December 2016 # # Author: # # John Burkardt # # Reference: # # Andrew Smith, # Fast construction of constant bound functions for sparse polynomials, # Journal of Global Optimization, # Volume 43, 2009, pages 445-458. # # Parameters: # # Input, integer M, the number of variables. # # Input, integer N, the number of points. # # Input, real X(M,N), the points. # # Output, integer VALUE(N), the value of the function at X. # value = ( \ 3.0 * x[0,0:n] ** 2 * x[1,0:n] ** 3 * x[2,0:n] ** 4 \ + x[0,0:n] ** 3 * x[1,0:n] * x[2,0:n] ** 3 \ - 5.0 * x[0,0:n] * x[1,0:n] * x[3,0:n] ** 5 \ + x[2,0:n] * x[3,0:n] * x[4,0:n] ** 3 ) return value def smith1_m ( ): #*****************************************************************************80 # ## SMITH1_M returns the number of variables in the smith1 problem. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 06 December 2016 # # Author: # # John Burkardt # # Reference: # # Andrew Smith, # Fast construction of constant bound functions for sparse polynomials, # Journal of Global Optimization, # Volume 43, 2009, pages 445-458. # # Parameters: # # Output, integer M, the number of variables. # m = 5 return m def smith1_test ( ): #*****************************************************************************80 # ## SMITH1_TEST uses sampling to estimate the range of the SMITH1 polynomial. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 06 December 2016 # # Author: # # John Burkardt # import platform from r8mat_uniform_abvec import r8mat_uniform_abvec print ( '' ) print ( 'SMITH1_TEST:' ) print ( ' Python version: %s' % ( platform.python_version ( ) ) ) print ( ' Use N sample values of a polynomial over its domain to estimate' ) print ( ' its minimum Pmin and maximum Pmax' ) print ( '' ) print ( ' N Pmin Pmax' ) print ( '' ) m = smith1_m ( ) l, u = smith1_b ( m ) print ( ' smith1: [ ?, ? ]:' ) seed = 123456789 n = 8 for n_log_2 in range ( 4, 21 ): n = n * 2 x, seed = r8mat_uniform_abvec ( m, n, u, l, seed ) f = smith1_f ( m, n, x ) print ( ' %8d %16.8g %16.8g' % ( n, min ( f ), max ( f ) ) ) # # Terminate. # print ( '' ) print ( 'SMITH1_TEST:' ) print ( ' Normal end of execution.' ) return if ( __name__ == '__main__' ): from timestamp import timestamp timestamp ( ) smith1_test ( ) timestamp ( )