Section 1.2A Catalog of Essential Functions

V63.0121, Calculus I

January 22, 2009

Announcements

I Blackboard is up

I First HW due Thursday 1/29

I ALEKS initial assessment due Friday 1/30

Outline

Modeling

Classes of FunctionsLinear functionsQuadratic functionsCubic functionsOther power functionsRational functionsTrigonometric FunctionsExponential and Logarithmic functions

Transformations of Functions

Compositions of Functions

The Modeling Process

Real-worldProblems

MathematicalModel

MathematicalConclusions

Real-worldPredictions

modelsolve

interpret

test

Plato’s Cave

The Modeling Process

Real-worldProblems

MathematicalModel

MathematicalConclusions

Real-worldPredictions

modelsolve

interpret

test

Shadows Forms

Outline

Modeling

Classes of FunctionsLinear functionsQuadratic functionsCubic functionsOther power functionsRational functionsTrigonometric FunctionsExponential and Logarithmic functions

Transformations of Functions

Compositions of Functions

Classes of Functions

I linear functions, defined by slope an intercept, point andpoint, or point and slope.

I quadratic functions, cubic functions, power functions,polynomials

I rational functions

I trigonometric functions

I exponential/logarithmic functions

Linear functions

Linear functions have a constant rate of growth and are of the form

f (x) = mx + b.

Example

In New York City taxis cost $2.50 to get in and $0.40 per 1/5 mile.Write the fare f (x) as a function of distance x traveled.

AnswerIf x is in miles and f (x) in dollars,

f (x) = 2.5 + 2x

Linear functions

Linear functions have a constant rate of growth and are of the form

f (x) = mx + b.

Example

In New York City taxis cost $2.50 to get in and $0.40 per 1/5 mile.Write the fare f (x) as a function of distance x traveled.

AnswerIf x is in miles and f (x) in dollars,

f (x) = 2.5 + 2x

Linear functions

Linear functions have a constant rate of growth and are of the form

f (x) = mx + b.

Example

In New York City taxis cost $2.50 to get in and $0.40 per 1/5 mile.Write the fare f (x) as a function of distance x traveled.

AnswerIf x is in miles and f (x) in dollars,

f (x) = 2.5 + 2x

Quadratic functions

These take the form

f (x) = ax2 + bx + c

The graph is a parabola which opens upward if a > 0, downward ifa < 0.

Quadratic functions

These take the form

f (x) = ax2 + bx + c

The graph is a parabola which opens upward if a > 0, downward ifa < 0.

Cubic functions

These take the form

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

Other power functions

I Whole number powers: f (x) = xn.

I negative powers are reciprocals: x−3 =1

x3.

I fractional powers are roots: x1/3 = 3√

x .

Rational functions

DefinitionA rational function is a quotient of polynomials.

Example

The function f (x) =x3(x + 3)

(x + 2)(x − 1)is rational.

Trigonometric Functions

I Sine and cosine

I Tangent and cotangent

I Secant and cosecant

Exponential and Logarithmic functions

I exponential functions (for example f (x) = 2x)

I logarithmic functions are their inverses (for examplef (x) = log2(x))

Outline

Modeling

Classes of FunctionsLinear functionsQuadratic functionsCubic functionsOther power functionsRational functionsTrigonometric FunctionsExponential and Logarithmic functions

Transformations of Functions

Compositions of Functions

Transformations of Functions

Take the sine function and graph these transformations:

I sin(x +

π

2

)I sin

(x − π

2

)I sin (x) +

π

2

I sin (x)− π

2

Observe that if the fiddling occurs within the function, atransformation is applied on the x-axis. After the function, to they -axis.

Transformations of Functions

Take the sine function and graph these transformations:

I sin(x +

π

2

)I sin

(x − π

2

)I sin (x) +

π

2

I sin (x)− π

2

Observe that if the fiddling occurs within the function, atransformation is applied on the x-axis. After the function, to they -axis.

Vertical and Horizontal Shifts

Suppose c > 0. To obtain the graph of

I y = f (x) + c , shift the graph of y = f (x) a distance c units

upward

I y = f (x)− c , shift the graph of y = f (x) a distance c units

downward

I y = f (x − c), shift the graph of y = f (x) a distance c units

to the right

I y = f (x + c), shift the graph of y = f (x) a distance c units

to the left

Vertical and Horizontal Shifts

Suppose c > 0. To obtain the graph of

I y = f (x) + c , shift the graph of y = f (x) a distance c unitsupward

I y = f (x)− c , shift the graph of y = f (x) a distance c units

downward

I y = f (x − c), shift the graph of y = f (x) a distance c units

to the right

I y = f (x + c), shift the graph of y = f (x) a distance c units

to the left

Vertical and Horizontal Shifts

Suppose c > 0. To obtain the graph of

I y = f (x) + c , shift the graph of y = f (x) a distance c unitsupward

I y = f (x)− c , shift the graph of y = f (x) a distance c unitsdownward

I y = f (x − c), shift the graph of y = f (x) a distance c units

to the right

I y = f (x + c), shift the graph of y = f (x) a distance c units

to the left

Vertical and Horizontal Shifts

Suppose c > 0. To obtain the graph of

I y = f (x) + c , shift the graph of y = f (x) a distance c unitsupward

I y = f (x)− c , shift the graph of y = f (x) a distance c unitsdownward

I y = f (x − c), shift the graph of y = f (x) a distance c unitsto the right

I y = f (x + c), shift the graph of y = f (x) a distance c units

to the left

Vertical and Horizontal Shifts

Suppose c > 0. To obtain the graph of

I y = f (x) + c , shift the graph of y = f (x) a distance c unitsupward

I y = f (x)− c , shift the graph of y = f (x) a distance c unitsdownward

I y = f (x − c), shift the graph of y = f (x) a distance c unitsto the right

I y = f (x + c), shift the graph of y = f (x) a distance c unitsto the left

Outline

Modeling

Classes of FunctionsLinear functionsQuadratic functionsCubic functionsOther power functionsRational functionsTrigonometric FunctionsExponential and Logarithmic functions

Transformations of Functions

Compositions of Functions

Composition is a compounding of functions in succession

f g

g ◦ f

x (g ◦ f )(x)f (x)

Composing

Example

Let f (x) = x2 and g(x) = sin x . Compute f ◦ g and g ◦ f .

Solutionf ◦ g(x) = sin2 x while g ◦ f (x) = sin(x2). Note they are not thesame.

Composing

Example

Let f (x) = x2 and g(x) = sin x . Compute f ◦ g and g ◦ f .

Solutionf ◦ g(x) = sin2 x while g ◦ f (x) = sin(x2). Note they are not thesame.

Decomposing

Example

Express√

x2 − 4 as a composition of two functions. What is itsdomain?

SolutionWe can write the expression as f ◦ g, where f (u) =

√u and

g(x) = x2 − 4. The range of g needs to be within the domain off . To insure that x2 − 4 ≥ 0, we must have x ≤ −2 or x ≥ 2.

The Far Side