scipy.integrate.simpson#
- scipy.integrate.simpson(y, x=None, dx=1.0, axis=- 1, even='avg')[source]#
Integrate y(x) using samples along the given axis and the composite Simpson’s rule. If x is None, spacing of dx is assumed.
If there are an even number of samples, N, then there are an odd number of intervals (N-1), but Simpson’s rule requires an even number of intervals. The parameter ‘even’ controls how this is handled.
- Parameters
- yarray_like
Array to be integrated.
- xarray_like, optional
If given, the points at which y is sampled.
- dxfloat, optional
Spacing of integration points along axis of x. Only used when x is None. Default is 1.
- axisint, optional
Axis along which to integrate. Default is the last axis.
- evenstr {‘avg’, ‘first’, ‘last’}, optional
- ‘avg’Average two results:1) use the first N-2 intervals with
a trapezoidal rule on the last interval and 2) use the last N-2 intervals with a trapezoidal rule on the first interval.
- ‘first’Use Simpson’s rule for the first N-2 intervals with
a trapezoidal rule on the last interval.
- ‘last’Use Simpson’s rule for the last N-2 intervals with a
trapezoidal rule on the first interval.
See also
quadadaptive quadrature using QUADPACK
rombergadaptive Romberg quadrature
quadratureadaptive Gaussian quadrature
fixed_quadfixed-order Gaussian quadrature
dblquaddouble integrals
tplquadtriple integrals
rombintegrators for sampled data
cumulative_trapezoidcumulative integration for sampled data
odeODE integrators
odeintODE integrators
Notes
For an odd number of samples that are equally spaced the result is exact if the function is a polynomial of order 3 or less. If the samples are not equally spaced, then the result is exact only if the function is a polynomial of order 2 or less.
Examples
>>> from scipy import integrate >>> x = np.arange(0, 10) >>> y = np.arange(0, 10)
>>> integrate.simpson(y, x) 40.5
>>> y = np.power(x, 3) >>> integrate.simpson(y, x) 1642.5 >>> integrate.quad(lambda x: x**3, 0, 9)[0] 1640.25
>>> integrate.simpson(y, x, even='first') 1644.5