Business Calculus

Functions
Functions Fundamentals
3 Topics
Functions and Their Representations: Potato Diagrams, Tables, Graphs, and Rules
Drawing Graphs by Point-Plotting
Function Domains, Codomains, and Ranges
PRAXIS: Functions Fundamentals
Linear Functions
2 Topics
Graphing Lines
Finding Equations of Lines
Quadratic and Polynomial Functions
2 Topics
Quadratic Functions and Their Graphs
Polynomials and Degree
PRAXIS: Linear, Quadratic, and Polynomial Functions
Exponential Functions
2 Topics
Exponential Functions: What They Are, and How to Evaluate Them
Graphing (Simple) Exponential Functions
Logarithmic Functions
3 Topics
Logarithmic Functions: What They Are, and How to Evaluate Them
Change-of-Base Formula and Computing Logs with a Calculator
Graphing (Simple) Logarithmic Functions
Constructing New Functions From Old Ones
4 Topics
Basic Function Arithmetic Using Function Rules, and Numerical Substitutions
Function Arithmetic: Using Tables to Evaluate Various Combinations of Functions at a Given Value
Function Arithmetic: Using Graphs to Evaluate Various Combinations of Functions at a Given Value
Piecewise Functions
PRAXIS: Exponential Functions, Logarithms, and Building New Functions From Old
Solving Equations with Functions
3 Topics
The Guess and Check Method for Solving Equations
Solving Equations Using Graphs
Algebraically Solving Equations
PRAXIS: Solving Functional Equations
Limits and Derivatives
Limits – An Overview
Left, Right, and Two-Sided Limits
3 Topics
Finding Limits Using Graphs
Guessing Limits Using Tables
Finding Limits Of Polynomials
PRAXIS: Limits
The Derivative as a Limit of an Average Rate of Change
4 Topics
Average Rates of Change
Finding Derivatives as a Limit of an Average Rate of Change
The h-Form of the Derivative and Finding Tangent Lines
The Derivative as a Function
PRAXIS: Derivatives Basics
Basic Derivative Rules
6 Topics
Deriving Polynomials Using the Power Rule and Simple Derivative Properties
Derivatives of Exponential Functions of the Form \(c\cdot e^x\)
Product Rule
Quotient Rule
Chain Rule
Derivatives of Logarithmic Functions
Finding Derivatives Using Several Different Rules
PRAXIS: Derivative Rules
Applications of Differentiation
Extrema: Finding Minima and Maxima
3 Topics
Finding Extrema by Graphing
First Derivative Test for Finding Local Mins and Maxes
First Derivative Test and Global Mins and Maxes
PRAXIS: Extrema
Concavity, Inflection Points, and the Second Derivative Test
3 Topics
Concavity and Inflection Points With Graphs
Concavity and Inflection Points Without Graphs
Second Derivative Test for Classifying Critical Points
PRAXIS: Concavity, Inflection Points, and Second Derivative Test
Optimization Applications
PRAXIS: Optimization Applications
Integration
Antiderivatives and Basic Rules for Such
2 Topics
The Power Rule for Antiderivatives
Initial Value Problems: Solving for C
The U-Substitution Method
3 Topics
How the Method Works
Using U-Sub with Exponential Functions
Antiderivatives that Result in Logarithms
PRAXIS: Antiderivatives
Area, Continuous Accumulation, and Definite Integrals
3 Topics
What Integrals Are and the Fundamental Theorem of Calculus
Computing Integrals Involving U-Substitution
Areas Between Curves
Average Value of a Function, and Moving Averages
2 Topics
Finding a Function’s Average Value Using Integrals
Moving Averages
PRAXIS: Area, Continuous Accumulation, and Definite Integrals
Compound Interest and Continuous Compounding
2 Topics
Compound Interest – Multiplying Your Money
The Natural Exponential Function and Continuous Compounding
Future Value of Income Streams
PRAXIS: Applications of Integration – Compound Interest and Future Value of Income Streams
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Graphing Lines

Business Calculus Linear Functions Graphing Lines

All linear functions and all linear equations can be written in the form \(y=mx+b\), called slope intercept form, where \(m\) is the slope or rate of change of the line, and \(b\) is the \(y\)-intercept of the line.

The rate of change \(m\) tells you how much the \(y\)-values of the function change given a certain change in \(x\).

For example, if given the equation for the line \(y=\frac{2}{3}x+1\), the slope is \(m=\frac{2}{3}\) which means “for every 3 I move to the right (i.e. change in \(x\)) from a chosen point on the line, I should move up 2 to land on another point on the line.”

To graph linear functions in slope intercept form \(f(x)=mx+b\), either use the method described in the video (easier), or do the following:

  1. First, plot the \(y\)-intercept \(b\) on the \(y\)-axis, noting that the line will cross through this point.
    • Aside: The reason the line crosses through this point is because \(f(0)=m(0)+b=b\); that is, when you plug in \(x=0\), and graph the corresponding \(y\)-value, you end up plotting \(y=b\) on the \(y\)-axis.
  2. Turn the slope into a fraction (if not already a fraction), by dividing the whole number (or decimal) by 1. (e.g. if the slope is \(m=3\) in the line equation, write instead \(m=\frac{3}{1}\).
  3. From the \(y\)-intercept you plotted, move to the right from that point according to the denominator of your slope, as found in the last step. Then, move up according to the value of the numerator of the slope found in the last step; plot a point there.
  4. Draw a line through both the \(y\)-intercept and the point just plotted so that the line extends infinitely in both directions.
Special Considerations:

If the function is constant (e.g. \(f(x)=5\)), then the graph is a flat line through the \(y\)-axis at \(y=5\).

This is because constant functions can be written as linear functions of the form \(f(x)=0x+b\), so no matter what the \(x\)-value is that is being plugged in, the output is always the same value, namely \(b\).

Such lines have zero slope.

Vertical lines can be written in the form \(x=c\) where \(c\) is a real number. Note that such lines do not represent a function of \(x\), but they DO represent a constant (and therefore linear function) in \(y\).

The examples below are practice for plotting lines from the slope-intercept form of a given function \(f(x)=mx+b\).

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