Graphs of elementary functions, graphs of polynomial functions

The graphs of the elementary functions

The graphs of algebraic and transcendental functions

The graphs of algebraic functions

The graphs of the polynomial functions

The source or original polynomial function

Translating (parallel shifting) of the polynomial function

Coordinates of translations and their role in the polynomial expression

The graph of the linear function

Elementary functions are, Algebraic functions and Transcendental functions

Algebraic functions

· The polynomial function f(x) = y = a_nxⁿ + a_n_-1xⁿ^-¹ + a_n_-2xⁿ^-² + . . . + a₂x² + a₁x + a₀

y = a₁x + a₀ - Linear function

y = a₂x² + a₁x + a₀- Quadratic function

y = a₃x³ + a₂x² + a₁x + a₀- Cubic function

y = a₄x⁴ + a₃x³ + a₂x² + a₁x + a₀- Quartic function

y = a₅x⁵ + a₄x⁴ + a₃x³ + a₂x² + a₁x + a₀- Quintic function

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· Rational functions - a ratio of two polynomials
	- Reciprocal function
	- Translation of the reciprocal function, called linear rational function.

The graphs of the polynomial functions

The graph of a function ƒ is drawing on the Cartesian plane, plotted with respect to coordinate axes, that shows functional relationship between variables. The points (x, ƒ(x)) lying on the curve satisfy this relation.

The source or original polynomial function

Any polynomial f(x) of degree n > 1 in the general form, consisting of n + 1 terms, shown graphically, represents translation of its source (original) function in the direction of the coordinate axes.

The source polynomial function

f_s(x) = a_nxⁿ + a_n_-₂xⁿ^-² + . . . + a₂x² + a₁x

has n - 1 terms lacking second and the constant term, since its coefficients, a_n_-₁= 0 and a₀= 0 while the leading coefficient a_n, remains unchanged.

Therefore, the source polynomial function passes through the origin.

A coefficient a_iof the source function is expressed by the coefficients of the general form.

Translating (parallel shifting) of the polynomial function

Thus, to obtain the graph of a given polynomial function f(x) we translate (parallel shift) the graph of its source function in the direction of the x-axis by x₀ and in the direction of the y-axis by y₀.

Inversely, to put a given graph of the polynomial function beck to the origin, we translate it in the opposite direction, by taking the values of the coordinates of translations with opposite sign.

Coordinates of translations and their role in the polynomial expression

The coordinates of translations we calculate using the formulas,

Hence, by plugging the coordinates of translations into the source polynomial function f_s(x), i.e.,

y - y₀ = a_n(x - x₀)ⁿ + a_n_-₂(x - x₀)ⁿ^-² + . . . + a₂(x - x₀)² + a₁(x - x₀)

and by expanding above expression we get the polynomial function in the general form

f(x) = y = a_nxⁿ + a_n_-1xⁿ^-¹ + a_n_-₂xⁿ^-² + . . . + a₂x² + a₁x + a₀.

Inversely, by plugging the coordinates of translations into the given polynomial f(x) expressed in the general form, i.e.,

y + y₀ = a_n(x + x₀)ⁿ + a_n_-₁(x + x₀)ⁿ^-¹ + . . . + a₁(x + x₀) + a₀

and after expanding and reducing above expression we get its source polynomial function.

Note that in the above expression the signs of the coordinates of translations are already changed.

Linear function y = a₁x + a₀

y = a₁x + a₀ or y = a₁(x - x₀) or y - y₀ = a₁x,

where x₀ = - a₀/a₁ and/or y₀ = a₀.

By setting x₀ = 0 or y₀ = 0 obtained is

the source linear y = a₁x.

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