Functions of one variable [−2,+3]. Also shown are the two real roots and the local minimum that are in the interval. The graph of the function f : \{1,2,3\} \to \{a,b,c,d\} defined by f(x)= \begin{cases} a, & \text{if }x=1, \\ d, & \text{if }x=2, \\ c, & \text{if }x=3, \end{cases} is the subset of the set \{1,2,3\} \times \{a,b,c,d\} G(f) = \{ (1,a), (2,d), (3,c) \}. From the graph, the domain \{1,2,3\} is recovered as the set of first component of each pair in the graph \{1,2,3\} = \{x :\ \exists y,\text{ such that }(x,y) \in G(f)\}. Similarly, the
range can be recovered as \{a,c,d\} = \{y : \exists x,\text{ such that }(x,y)\in G(f)\}. The codomain \{a,b,c,d\}, however, cannot be determined from the graph alone. The graph of the cubic polynomial on the
real line f(x) = x^3 - 9x is \{ (x, x^3 - 9x) : x \text{ is a real number} \}. If this set is plotted on a
Cartesian plane, the result is a curve (see figure).
Functions of two variables The graph of the
trigonometric function f(x,y) = \sin(x^2)\cos(y^2) is \{ (x, y, \sin(x^2) \cos(y^2)) : x \text{ and } y \text{ are real numbers} \}. If this set is plotted on a
three dimensional Cartesian coordinate system, the result is a surface (see figure). Oftentimes it is helpful to show with the graph, the gradient of the function and several level curves. The level curves can be mapped on the function surface or can be projected on the bottom plane. The second figure shows such a drawing of the graph of the function: f(x, y) = -(\cos(x^2) + \cos(y^2))^2. == See also ==