std::comp_ellint_1, std::comp_ellint_1f, std::comp_ellint_1l
<cmath>
float comp_ellint_1 ( float k );
(until C++23)
<cmath>
double comp_ellint_1 ( Integer k );
std::comp_ellint_1
for all cv-unqualified floating-point types as the type of the parameter k.(since C++23)[edit] Parameters
[edit] Return value
If no errors occur, value of the complete elliptic integral of the first kind of k, that is std::ellint_1 (k, π/2), is returned.
[edit] 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.
[edit] 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 additional overloads are not required to be provided exactly as (A). They only need to be sufficient to ensure that for their argument num of integer type, std::comp_ellint_1(num) has the same effect as std::comp_ellint_1(static_cast<double>(num)).
[edit] Example
The period of a pendulum of length l, given acceleration due to gravity g, and initial angle θ equals 4⋅√l/g⋅K(sin(θ/2)), where K is std::comp_ellint_1
.
#include <cmath> #include <iostream> #include <numbers> int main() { constexpr double π{std::numbers::pi }; std::cout << "K(0) ≈ " << std::comp_ellint_1(0) << '\n' << "π/2 ≈ " << π / 2 << '\n' << "K(0.5) ≈ " << std::comp_ellint_1(0.5) << '\n' << "F(0.5, π/2) ≈ " << std::ellint_1 (0.5, π / 2) << '\n' << "The period of a pendulum length 1m at 10° initial angle ≈ " << 4 * std::sqrt (1 / 9.80665) * std::comp_ellint_1(std::sin (π / 18 / 2)) << "s,\n" "whereas the linear approximation gives ≈ " << 2 * π * std::sqrt (1 / 9.80665) << '\n'; }
Output:
K(0) ≈ 1.5708 π/2 ≈ 1.5708 K(0.5) ≈ 1.68575 F(0.5, π/2) ≈ 1.68575 The period of a pendulum length 1 m at 10° initial angle ≈ 2.01024s, whereas the linear approximation gives ≈ 2.00641