std::comp_ellint_2, std::comp_ellint_2f, std::comp_ellint_2l
Defined in header <cmath>
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double comp_ellint_2( double k); float comp_ellint_2( float k ); |
(1) | (since C++17) |
double comp_ellint_2( IntegralType k ); |
(2) | (since C++17) |
Contents |
Parameters
k | - | elliptic modulus or eccentricity (a value of a floating-point or integral type) |
Return value
If no errors occur, value of the complete elliptic integral of the second kind of k
, that is ellint_2(k,π/2), is returned.
Error handling
Errors may be reported as specified in math_errhandling.
- If the argument is NaN, NaN is returned and domain error is not reported.
- If |k|>1, a domain error may occur.
Notes
Implementations that do not support C++17, but support ISO 29124:2010, provide this function if __STDCPP_MATH_SPEC_FUNCS__
is defined by the implementation to a value at least 201003L and if the user defines __STDCPP_WANT_MATH_SPEC_FUNCS__
before including any standard library headers.
Implementations that do not support ISO 29124:2010 but support TR 19768:2007 (TR1), provide this function in the header tr1/cmath
and namespace std::tr1
.
An implementation of this function is also available in boost.math.
The perimeter of an ellipse with eccentricity k
and semimajor axis a equals 4aE(k), where E is std::comp_ellint_2
. When eccentricity equals 0, the ellipse degenerates to a circle with radius a and the perimeter equals 2πa, so E(0) = π/2. When eccentricity equals 1, the ellipse degenerates to a line of length 2a, whose perimeter is 4a, so E(1) = 1.
Example
#include <cmath> #include <iostream> #include <numbers> int main() { constexpr double hpi = std::numbers::pi / 2.0; std::cout << "E(0) = " << std::comp_ellint_2(0) << '\n' << "π/2 = " << hpi << '\n' << "E(1) = " << std::comp_ellint_2(1) << '\n' << "E(1, π/2) = " << std::ellint_2(1, hpi) << '\n'; }
Output:
E(0) = 1.5708 π/2 = 1.5708 E(1) = 1 E(1, π/2) = 1
See also
(C++17)(C++17)(C++17) |
(incomplete) elliptic integral of the second kind (function) |
External links
Weisstein, Eric W. "Complete Elliptic Integral of the Second Kind." From MathWorld — A Wolfram Web Resource. |