∫Calculus I Unit 1 – Functions and Graphs

Functions and graphs form the foundation of calculus, providing a visual and mathematical way to represent relationships between variables. This unit explores various types of functions, their properties, and graphing techniques, setting the stage for more advanced calculus concepts. Understanding function transformations, compositions, and inverses is crucial for analyzing complex relationships. These tools allow us to manipulate and combine functions, enabling us to model real-world phenomena and solve intricate mathematical problems in calculus and beyond.

Study Guides for Unit 1

1.1

Review of Functions

5 min read

1.2

Basic Classes of Functions

4 min read

1.3

Trigonometric Functions

3 min read

1.4

Inverse Functions

3 min read

1.5

Exponential and Logarithmic Functions

3 min read

Key Concepts

Functions map input values from the domain to output values in the range
The vertical line test determines if a relation is a function
Piecewise functions consist of multiple sub-functions, each defined over a different interval of the domain
Inverse functions "undo" each other, satisfying $f(f^{-1}(x))=f^{-1}(f(x))=x$
Transformations of functions include shifts, reflections, and scaling
Composition of functions combines two or more functions into a single function
Limit notation describes the behavior of a function as the input approaches a certain value
Continuity requires a function to be defined at a point, the limit to exist, and the limit to equal the function value

Function Basics

A function $f$ $f$ is a rule that assigns a unique output $f(x)$ $f (x)$ to each input $x$ $x$ in the domain
- The domain is the set of all possible input values
- The range is the set of all possible output values
Functions can be represented using equations, graphs, or tables
The vertical line test states that if any vertical line intersects a graph more than once, the graph does not represent a function
One-to-one functions have a unique output for each input and pass the horizontal line test
Even and odd functions exhibit symmetry about the y-axis and origin, respectively
- Even functions satisfy $f(-x)=f(x)$
- Odd functions satisfy $f(-x)=-f(x)$
Increasing functions have outputs that increase as inputs increase, while decreasing functions have outputs that decrease as inputs increase

Types of Functions

Linear functions have the form $f(x)=mx+b$ , where $m$ is the slope and $b$ is the y-intercept
Quadratic functions have the form $f(x)=ax^2+bx+c$ $f (x) = a x^{2} + b x + c$ , where $a$ $a$ , $b$ $b$ , and $c$ $c$ are constants and $a \neq 0$ $a \neq = 0$
- The graph of a quadratic function is a parabola
Polynomial functions are the sum of terms with non-negative integer exponents (linear, quadratic, cubic)
Rational functions are the quotient of two polynomial functions, often involving asymptotes and holes
Exponential functions have the form $f(x)=a^x$ , where $a>0$ and $a \neq 1$
Logarithmic functions have the form $f(x)=\log_a(x)$ $f (x) = lo g_{a} (x)$ , where $a>0$ $a > 0$ , $a \neq 1$ $a \neq = 1$ , and $x>0$ $x > 0$
- Logarithmic functions are the inverses of exponential functions
Trigonometric functions (sine, cosine, tangent) relate angles to side lengths in right triangles and have periodic behavior

Graphing Techniques

To graph a function, plot points by evaluating the function at various input values
Determine the domain and range of a function by considering the graph or equation
Identify intercepts by setting $x=0$ (y-intercept) or $y=0$ (x-intercepts)
Analyze asymptotes, which are lines that the graph approaches but never touches
- Vertical asymptotes occur when the denominator of a rational function equals zero
- Horizontal asymptotes describe the behavior of a function as $x$ approaches positive or negative infinity
Use symmetry (even, odd) to simplify the graphing process
Sketch piecewise functions by graphing each sub-function on its respective domain interval
Utilize transformations to graph functions more efficiently

Transformations of Functions

Transformations alter the graph of a function without changing its basic shape
Vertical shifts move the graph up or down and have the form $f(x)+k$ (up for $k>0$ , down for $k<0$ )
Horizontal shifts move the graph left or right and have the form $f(x-h)$ (right for $h>0$ , left for $h<0$ )
Reflections flip the graph across the x-axis ( $-f(x)$ ) or y-axis ( $f(-x)$ )
Vertical scaling stretches ( $|a|>1$ $∣ a ∣ > 1$ ) or compresses ( $0<|a|<1$ $0 < ∣ a ∣ < 1$ ) the graph vertically and has the form $af(x)$ $a f (x)$
- For $a<0$ , the graph is also reflected across the x-axis
Horizontal scaling stretches ( $0<|a|<1$ ) or compresses ( $|a|>1$ ) the graph horizontally and has the form $f(ax)$
Combining transformations requires applying them in the correct order: scaling, reflection, horizontal shift, vertical shift

Function Operations

Function addition $(f+g)(x)=f(x)+g(x)$ adds the output values of two functions for each input value
Function subtraction $(f-g)(x)=f(x)-g(x)$ subtracts the output values of two functions for each input value
Function multiplication $(fg)(x)=f(x)g(x)$ multiplies the output values of two functions for each input value
Function division $(\frac{f}{g})(x)=\frac{f(x)}{g(x)}$ divides the output values of two functions for each input value, provided $g(x) \neq 0$
Composition of functions $(f \circ g)(x)=f(g(x))$ $(f \circ g) (x) = f (g (x))$ applies one function to the output of another function
- The domain of the composite function is the set of all $x$ in the domain of $g$ such that $g(x)$ is in the domain of $f$
Finding the inverse of a function $f^{-1}(x)$ $f^{- 1} (x)$ involves solving the equation $y=f(x)$ $y = f (x)$ for $x$ $x$ in terms of $y$ $y$ , then swapping $x$ $x$ and $y$ $y$
- The domain of $f^{-1}$ is the range of $f$ , and the range of $f^{-1}$ is the domain of $f$

Applications in Calculus

Limits describe the behavior of a function as the input approaches a specific value or infinity
- Limits are essential for defining continuity, derivatives, and integrals
Continuity requires a function to have no gaps, jumps, or breaks in its graph
- Continuous functions are necessary for many theorems and applications in calculus
Derivatives represent the instantaneous rate of change of a function at a given point
- Derivatives are used to find slopes of tangent lines, optimize functions, and analyze motion
Integrals calculate the area under a curve, which can represent quantities such as displacement, work, and volume
- The Fundamental Theorem of Calculus connects derivatives and integrals, enabling the calculation of areas and volumes

Common Pitfalls and Tips

Remember that not all relations are functions; always check using the vertical line test
Be careful when applying transformations; follow the correct order and sign conventions
When finding the domain of a rational function, set the denominator equal to zero and exclude those values from the domain
Ensure that the domain and range of a function align with its context in real-world applications
When composing functions, work from the inside out, and pay attention to the order of the functions
Remember that inverse functions "undo" each other; if $f(a)=b$ , then $f^{-1}(b)=a$
Sketch a graph to visualize a problem before attempting to solve it algebraically
Double-check your work by plugging your answer back into the original equation or problem