#! /usr/bin/env python # def r8_acosh ( x ): #*****************************************************************************80 # ## R8_ACOSH evaluates the arc-hyperbolic cosine of an R8 argument. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 25 July 2014 # # Author: # # Original FORTRAN77 version by Wayne Fullerton. # Python version by John Burkardt. # # Reference: # # Wayne Fullerton, # Portable Special Function Routines, # in Portability of Numerical Software, # edited by Wayne Cowell, # Lecture Notes in Computer Science, Volume 57, # Springer 1977, # ISBN: 978-3-540-08446-4, # LC: QA297.W65. # # Parameters: # # Input, real X, the argument. # # Output, real VALUE, the arc-hyperbolic cosine of X. # import numpy as np from sys import exit if ( x < 1.0 ): print ( '' ) print ( 'R8_ACOSH - Fatal error!' ) print ( ' X < 1.0' ) exit ( 'R8_ACOSH - Fatal error!' ) r8_tiny = 1.0E-30 xmax = 1.0 / np.sqrt ( r8_tiny ) if ( x < xmax ): value = np.log ( x + np.sqrt ( x * x - 1.0 ) ) else: dln2 = 0.69314718055994530941723212145818 value = dln2 + np.log ( x ) return value def r8_acosh_test ( ): #*****************************************************************************80 # ## R8_ACOSH_TEST tests R8_ACOSH. # # Licensing: # # This code is distributed under the GNU LGPL license. # # Modified: # # 25 July 2014 # # Author: # # John Burkardt # import platform import numpy as np print ( '' ) print ( 'R8_ACOSH_TEST' ) print ( ' Python version: %s' % ( platform.python_version ( ) ) ) print ( ' R8_ACOSH computes the arc-hyperbolic-cosine of an angle.' ) print ( '' ) print ( ' X A=R8_ACOSH(X) COSH(A)' ) print ( '' ) for test in range ( 0, 9 ): x = 1.0 + ( test ) / 2.0 a = r8_acosh ( x ) x2 = np.cosh ( a ) print ( ' %14.6g %14.6g %14.6g' % ( x, a, x2 ) ) # # Terminate. # print ( '' ) print ( 'R8_ACOSH_TEST' ) print ( ' Normal end of execution.' ) return if ( __name__ == '__main__' ): from timestamp import timestamp timestamp ( ) r8_acosh_test ( ) timestamp ( )