Unit 6: Functions




               If f(x ) > f(x ) when x  < x , then f(x) is increasing.                          Notes
                   2    1      1   2
               If f(x ) < f(x ) when x  < x , then f(x) is decreasing.
                   2    1      1   2
               If f(x ) = f(x ) for all values of x  and x  in I, then f(x) is constant.
                   2    1              1     2
               If, however, the strict inequality holds in the above statements, then f(x) is strictly increasing
               (or decreasing) function.
          2.   Monotonic Function
               A function y = f(x) is said to be monotonic if y is either increasing or decreasing over its
               domain, as x increases.
               If the function is increasing (decreasing) over its domain, it is called monotonically increasing
               (decreasing) function.
               A monotonic function is also termed as a one to one function.
          3.   Implicit and Explicit Function
               When a relationship between  x and y is written as  y = f(x), it is said to  be an explicit
               function. If the same relation is written as F(x, y) = 0, it is said to be an implicit function.
               Production  possibility function or the transformation function is often expressed as an
               implicit function.
          4.   Inverse Function
               If a function y = f(x) is such that for each element of the range we can associate a unique
               element of the domain (i.e. one to one function), then the inverse of the function, denoted
                    –1
               as x = f (y) g(y), is obtained by solving y = f(x) for x in terms of y. The functions f(x) and g(y)
               are said to be inverse of each other and can be written as either g[f(x)] = x or f[g(y)] = y. We
               note here that an implicit function F(x, y) = 0, can be expressed as two explicit functions
               that are inverse of each other.
          5.   Symmetry of a Function
               Symmetry of a function is often helpful in sketching its graph. Following types of symmetry
               are often useful:
               (i)  Symmetry about y-axis
                    A function y = f(x) is said to be symmetric about y-axis if f(–x) = f(x) for all x in its
                    domain. For example, the function y = x  is symmetric about y-axis. Such a function
                                                    2
                    is also known as even function.
                    Similarly, if g(y) = g(–y), then the function x = g(y) is said to be symmetric about x-
                    axis.
               (ii)  Symmetry about the line x = h

                    A function y = f(x) is said to be symmetric about the line x = h if f(h – k) = f(h + k) for
                    all real value k.
               (iii)  Symmetry about origin

                    A function y = f(x) is said to be symmetric about origin if f(–x) = –f(x), for all values
                                                            2
                    of x in its domain. For example, the function y = x  is symmetric about origin. Such
                    a function is also known as odd function.
               (iv)  Symmetry about the line y = x (45° line)
                    Two functions are said  to be  symmetrical about  the line  y =  x (45° line), if the
                    interchange of x and y in one function gives the other function. This type of symmetry


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