Cubic function

In mathematics, a cubic function is a function of the form

where the coefficients a, b, c, and d are real numbers, and the variable x takes real values, and a ≠ 0. In other words, it is both a polynomial function of degree three, and a real function. In particular, the domain and the codomain are the set of the real numbers.

Setting f(x) = 0 produces a cubic equation of the form

whose solutions are called roots of the function.

A cubic function has either one or three real roots (the existence of at least one real root is true for all odd-degree polynomial functions).

The graph of a cubic function always has a single inflection point. It may have two critical points, a local minimum and a local maximum. Otherwise, a cubic function is monotonic. The graph of a cubic function is symmetric with respect to its inflection point; that is, it is invariant under a rotation of a half turn around this point. Up to an affine transformation, there are only three possible graphs for cubic functions.

Cubic functions are fundamental for cubic interpolation.

History

Critical and inflection points

The critical points of a cubic function are its stationary points, that is the points where the slope of the function is zero. Thus the critical points of a cubic function f defined by

f(x) = ax3 + bx2 + cx + d,

occur at values of x such that the derivative

of the cubic function is zero.

The solutions of this equation are the x-values of the critical points and are given, using the quadratic formula, by

The sign of the expression inside the square root determines the number of critical points. If it is positive, then there are two critical points, one is a local maximum, and the other is a local minimum. If b2 – 3ac = 0, then there is only one critical point, which is an inflection point. If b2 – 3ac < 0, then there are no (real) critical points. In the two latter cases, that is, if b2 – 3ac is nonpositive, the cubic function is strictly monotonic. See the figure for an example of the case Δ0 > 0.

The inflection point of a function is where that function changes concavity. An inflection point occurs when the second derivative is zero, and the third derivative is nonzero. Thus a cubic function has always a single inflection point, which occurs at

Classification

The graph of a cubic function is an example of a cubic curve. (Many cubic curves are not graphs of functions.)

Although cubic functions depend on four parameters, their graph can have only very few shapes. In fact, the graph of a cubic function is always similar to the graph of a function of the form

This similarity can be built as the composition of translations parallel to the coordinates axes, a homothecy (uniform scaling), and, possibly, a reflection (mirror image) with respect to the y-axis. A further non-uniform scaling can transform the graph into the graph of one among the three cubic functions

This means that there is only three graphs of cubic functions up to an affine transformation.

The above geometric transformations can be built in the following way, when starting from a general cubic function

Firstly, if a < 0, the change of variable x → –x allows supposing a > 0. After this change of variable, the new graph is the mirror image of the previous one, with respect of the y-axis.

Then, the change of variable x = x1b/3a provides a function of the form

This corresponds to a translation parallel to the x-axis.

The change of variable y = y1 + q corresponds to a translation with respect to the y-axis, and gives a function of the form

The change of variable corresponds to a uniform scaling, and give, after division by a function of the form

which is the simplest form that can be obtained by a similarity.

Then, if p ≠ 0, the non-uniform scaling gives, after division by

where has the value 1 or –1, depending on the sign of p. If one defines the latter form of the function applies to all cases.

Symmetry

For a cubic function of the form the inflection point is thus the origin. As such a function is an odd function, its graph is symmetric with respect to the inflection point, and invariant under a rotation of a half turn around the inflection point. As these propertices are invariant by similarity, the following is true for all cubic functions.

The graph of a cubic function is symmetric with respect to its inflection point, and is invariant under a rotation of a half turn around the inflection point.

Collinearities

The tangent lines to the graph of a cubic function at three collinear points intercept the cubic again at collinear points.[1] This can be seen as follows.

As this property is invariant under a rigid motion, one may suppose that the function has the form

If α is a real number, then the tangent to the graph of f at the point (α, f(α)) is the line

{(x, f(α) + (xα)f′(α)) : xR}.

So, the intersection point between this line and the graph of f can be obtained solving the equation f(x) = f(α) + (xα)f′(α), that is

which can be rewritten

and factorized as

So, the tangent intercepts the cubic at

So, the function that maps a point (x, y) of the graph to the other point where the tangent intercepts the graph is

This is an affine transformation that transforms collinear points into collinear points. This proves the claimed result.

Cubic interpolation

Given the values of a function and its derivative at two points, there is exactly one cubic function that has the same four values, which is called a cubic Hermite spline.

There are two standard ways for using this fact. Firstly, if one knows, for example by physical measurement, the values of a function and its derivative at some sampling points, one can interpolate the function with a continuously differentiable function, which is a piecewise cubic function.

If the value of a function is known at several points, cubic interpolation consists in approximating the function by a continuously differentiable function, which is piecewise cubic. For having a uniquely defined interpolation, two more constraints must be added, such as the values of the derivatives at the endpoints, or a zero curvature at the endpoints.

Reference

  1. Whitworth, William Allen (1866), "Equations of the third degree", Trilinear Coordinates and Other Methods of Modern Analytical Geometry of Two Dimensions, Cambridge: Deighton, Bell, and Co., p. 425, retrieved June 17, 2016
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