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Trig (3)
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    NAME

         Math::Trig - trigonometric functions
    
    
    

    SYNOPSIS

                 use Math::Trig;
    
                 $x = tan(0.9);
                 $y = acos(3.7);
                 $z = asin(2.4);
    
                 $halfpi = pi/2;
    
                 $rad = deg2rad(120);
    
    
    
    

    DESCRIPTION

         Math::Trig defines many trigonometric functions not defined
         by the core Perl which defines only the sin() and cos().
         The constant pi is also defined as are a few convenience
         functions for angle conversions.
    
    
    

    TRIGONOMETRIC FUNCTIONS

         The tangent
    
         tan
    
         The cofunctions of the sine, cosine, and tangent (cosec/csc
         and cotan/cot are aliases)
    
         csc, cosec, sec, sec, cot, cotan
    
         The arcus (also known as the inverse) functions of the sine,
         cosine, and tangent
    
         asin, acos, atan
    
         The principal value of the arc tangent of y/x
    
         atan2(y, x)
    
         The arcus cofunctions of the sine, cosine, and tangent
         (acosec/acsc and acotan/acot are aliases)
    
         acsc, acosec, asec, acot, acotan
    
         The hyperbolic sine, cosine, and tangent
    
         sinh, cosh, tanh
    
         The cofunctions of the hyperbolic sine, cosine, and tangent
         (cosech/csch and cotanh/coth are aliases)
    
         csch, cosech, sech, coth, cotanh
    
         The arcus (also known as the inverse) functions of the
         hyperbolic sine, cosine, and tangent
    
         asinh, acosh, atanh
    
         The arcus cofunctions of the hyperbolic sine, cosine, and
         tangent (acsch/acosech and acoth/acotanh are aliases)
    
         acsch, acosech, asech, acoth, acotanh
    
         The trigonometric constant pi is also defined.
    
         $pi2 = 2 * pi;
    
         ERRORS DUE TO DIVISION BY ZERO
    
         The following functions
    
                 acoth
                 acsc
                 acsch
                 asec
                 asech
                 atanh
                 cot
                 coth
                 csc
                 csch
                 sec
                 sech
                 tan
                 tanh
    
         cannot be computed for all arguments because that would mean
         dividing by zero or taking logarithm of zero. These
         situations cause fatal runtime errors looking like this
    
                 cot(0): Division by zero.
                 (Because in the definition of cot(0), the divisor sin(0) is 0)
                 Died at ...
    
         or
    
                 atanh(-1): Logarithm of zero.
                 Died at...
    
         For the csc, cot, asec, acsc, acot, csch, coth, asech,
         acsch, the argument cannot be 0 (zero).  For the atanh,
         acoth, the argument cannot be 1 (one).  For the atanh,
         acoth, the argument cannot be -1 (minus one).  For the tan,
         sec, tanh, sech, the argument cannot be pi/2 + k * pi, where
         k is any integer.
    
         SIMPLE (REAL) ARGUMENTS, COMPLEX RESULTS
    
         Please note that some of the trigonometric functions can
         break out from the real axis into the complex plane. For
         example asin(2) has no definition for plain real numbers but
         it has definition for complex numbers.
    
         In Perl terms this means that supplying the usual Perl
         numbers (also known as scalars, please see the perldata
         manpage) as input for the trigonometric functions might
         produce as output results that no more are simple real
         numbers: instead they are complex numbers.
    
         The Math::Trig handles this by using the Math::Complex
         package which knows how to handle complex numbers, please
         see the Math::Complex manpage for more information. In
         practice you need not to worry about getting complex numbers
         as results because the Math::Complex takes care of details
         like for example how to display complex numbers. For
         example:
    
                 print asin(2), "\n";
    
         should produce something like this (take or leave few last decimals):
    
                 1.5707963267949-1.31695789692482i
    
         That is, a complex number with the real part of
         approximately 1.571 and the imaginary part of approximately
         -1.317.
    
    
    

    PLANE ANGLE CONVERSIONS

         (Plane, 2-dimensional) angles may be converted with the
         following functions.
    
                 $radians  = deg2rad($degrees);
                 $radians  = grad2rad($gradians);
    
                 $degrees  = rad2deg($radians);
                 $degrees  = grad2deg($gradians);
    
                 $gradians = deg2grad($degrees);
                 $gradians = rad2grad($radians);
    
         The full circle is 2 pi radians or 360 degrees or 400
         gradians.
    
    
    

    RADIAL COORDINATE CONVERSIONS

         Radial coordinate systems are the spherical and the
         cylindrical systems, explained shortly in more detail.
    
         You can import radial coordinate conversion functions by
         using the :radial tag:
    
             use Math::Trig ':radial';
    
             ($rho, $theta, $z)     = cartesian_to_cylindrical($x, $y, $z);
             ($rho, $theta, $phi)   = cartesian_to_spherical($x, $y, $z);
             ($x, $y, $z)           = cylindrical_to_cartesian($rho, $theta, $z);
             ($rho_s, $theta, $phi) = cylindrical_to_spherical($rho_c, $theta, $z);
             ($x, $y, $z)           = spherical_to_cartesian($rho, $theta, $phi);
             ($rho_c, $theta, $z)   = spherical_to_cylindrical($rho_s, $theta, $phi);
    
         All angles are in radians.
    
         COORDINATE SYSTEMS
    
         Cartesian coordinates are the usual rectangular (x, y,
         z)-coordinates.
    
         Spherical coordinates, (rho, theta, pi), are three-
         dimensional coordinates which define a point in three-
         dimensional space.  They are based on a sphere surface.  The
         radius of the sphere is rho, also known as the radial
         coordinate.  The angle in the xy-plane (around the z-axis)
         is theta, also known as the azimuthal coordinate.  The angle
         from the z-axis is phi, also known as the polar coordinate.
         The `North Pole' is therefore 0, 0, rho, and the `Bay of
         Guinea' (think of the missing big chunk of Africa) 0, pi/2,
         rho.  In geographical terms phi is latitude (northward
         positive, southward negative) and theta is longitude
         (eastward positive, westward negative).
    
         BEWARE: some texts define theta and phi the other way round,
         some texts define the phi to start from the horizontal
         plane, some texts use r in place of rho.
    
         Cylindrical coordinates, (rho, theta, z), are three-
         dimensional coordinates which define a point in three-
         dimensional space.  They are based on a cylinder surface.
         The radius of the cylinder is rho, also known as the radial
         coordinate.  The angle in the xy-plane (around the z-axis)
         is theta, also known as the azimuthal coordinate.  The third
         coordinate is the z, pointing up from the theta-plane.
    
         3-D ANGLE CONVERSIONS
    
         Conversions to and from spherical and cylindrical
         coordinates are available.  Please notice that the
         conversions are not necessarily reversible because of the
         equalities like pi angles being equal to -pi angles.
         cartesian_to_cylindrical
    
                     ($rho, $theta, $z) = cartesian_to_cylindrical($x, $y, $z);
    
    
         cartesian_to_spherical
    
                     ($rho, $theta, $phi) = cartesian_to_spherical($x, $y, $z);
    
    
         cylindrical_to_cartesian
    
                     ($x, $y, $z) = cylindrical_to_cartesian($rho, $theta, $z);
    
    
         cylindrical_to_spherical
    
                     ($rho_s, $theta, $phi) = cylindrical_to_spherical($rho_c, $theta, $z);
    
             Notice that when $z is not 0 $rho_s is not equal to
             $rho_c.
    
         spherical_to_cartesian
    
                     ($x, $y, $z) = spherical_to_cartesian($rho, $theta, $phi);
    
    
         spherical_to_cylindrical
    
                     ($rho_c, $theta, $z) = spherical_to_cylindrical($rho_s, $theta, $phi);
    
             Notice that when $z is not 0 $rho_c is not equal to
             $rho_s.
    
    
    

    GREAT CIRCLE DISTANCES

         You can compute spherical distances, called great circle
         distances, by importing the great_circle_distance function:
    
                 use Math::Trig 'great_circle_distance'
    
           $distance = great_circle_distance($theta0, $phi0, $theta1, $phi1, [, $rho]);
    
         The great circle distance is the shortest distance between
         two points on a sphere.  The distance is in $rho units.  The
         $rho is optional, it defaults to 1 (the unit sphere),
         therefore the distance defaults to radians.
    
         If you think geographically the theta are longitudes: zero
         at the Greenwhich meridian, eastward positive, westward
         negative--and the phi are latitudes: zero at the North Pole,
         northward positive, southward negative.  NOTE: this formula
         thinks in mathematics, not geographically: the phi zero is
         at the North Pole, not at the Equator on the west coast of
         Africa (Bay of Guinea).  You need to subtract your
         geographical coordinates from pi/2 (also known as 90
         degrees).
    
           $distance = great_circle_distance($lon0, pi/2 - $lat0,
                                             $lon1, pi/2 - $lat1, $rho);
    
    
    
    

    EXAMPLES

         To calculate the distance between London (51.3N 0.5W) and
         Tokyo (35.7N 139.8E) in kilometers:
    
                 use Math::Trig qw(great_circle_distance deg2rad);
    
                 # Notice the 90 - latitude: phi zero is at the North Pole.
                 @L = (deg2rad(-0.5), deg2rad(90 - 51.3));
                 @T = (deg2rad(139.8),deg2rad(90 - 35.7));
    
                 $km = great_circle_distance(@L, @T, 6378);
    
         The answer may be off by few percentages because of the
         irregular (slightly aspherical) form of the Earth.
    
    
    

    BUGS

         Saying use Math::Trig; exports many mathematical routines in
         the caller environment and even overrides some (sin, cos).
         This is construed as a feature by the Authors, actually...
         ;-)
    
         The code is not optimized for speed, especially because we
         use Math::Complex and thus go quite near complex numbers
         while doing the computations even when the arguments are
         not. This, however, cannot be completely avoided if we want
         things like asin(2) to give an answer instead of giving a
         fatal runtime error.
    
    
    

    AUTHORS

         Jarkko Hietaniemi <jhi@iki.fi> and Raphael Manfredi
         <Raphael_Manfredi@grenoble.hp.com>.
    
    
    
    


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