BackCalculus I: Foundations, Limits, and Derivatives
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Numbers and Functions
1.1 Different Kinds of Numbers
Calculus begins with understanding the types of numbers used in mathematics. The positive integers are 1, 2, 3, ...; the negative integers are ..., -3, -2, -1. Together, these form the integers. Rational numbers are fractions of integers, and real numbers include all rational and irrational numbers (such as and ).
Rational numbers: Numbers that can be written as , where and are integers and .
Irrational numbers: Numbers that cannot be written as a ratio of integers (e.g., , ).
Real numbers: All rational and irrational numbers, represented on the number line.
Example: is irrational because it cannot be written as a fraction of two integers.
1.2 The Real Number Line and Intervals
The real numbers can be visualized as points on a line. Intervals are subsets of real numbers between two endpoints.
Closed interval: includes both endpoints and .
Open interval: excludes both endpoints.
Half-open intervals: or include only one endpoint.
Example: is the set of all real numbers such that .
1.3 Sets and Set Operations
Sets are collections of objects (numbers). The union of two sets and is the set of elements in either or . The intersection is the set of elements in both and .
Union:
Intersection:
Functions
3.1 Definition of a Function
A function assigns to each element in a set exactly one element in a set . The set is the domain, and the set of all possible is the range.
Notation:
Example: with domain and range .
3.2 Linear Functions
A linear function has the form , where is the slope and is the y-intercept. Its graph is a straight line.
Example:
3.3 Domain and Range
The domain of a function is the set of all input values for which the function is defined. The range is the set of all possible output values.
Example: For , the domain is and the range is .
3.4 Inverse Functions
An inverse function reverses the effect of , so that and for all in the domain of .
Example: If , then .
Limits and Continuity
2.1 Informal Definition of Limit
The limit of as approaches is if gets arbitrarily close to as gets arbitrarily close to .
Notation:
Example:
2.2 Formal Definition of Limit (Epsilon-Delta)
For every , there exists such that if , then .
2.3 Properties of Limits
Sum:
Product:
Quotient: , provided
2.4 Left and Right Limits
Left-hand limit:
Right-hand limit:
The limit exists if and only if both one-sided limits exist and are equal.
2.5 Continuity
A function is continuous at if .
Polynomials and rational functions are continuous on their domains.
Derivatives
3.1 Definition of the Derivative
The derivative of at is the limit:
It represents the instantaneous rate of change of at .
The derivative is the slope of the tangent line to the graph of at .
3.2 Notation
Lagrange:
Leibniz:
3.3 Differentiation Rules
Rule | Formula |
|---|---|
Constant Rule | |
Power Rule | |
Sum Rule | |
Product Rule | |
Quotient Rule |
3.4 Differentiability and Continuity
If a function is differentiable at a point, it is also continuous at that point. However, continuity does not guarantee differentiability.
Example: is continuous everywhere but not differentiable at .
3.5 Applications of the Derivative
Instantaneous velocity: The derivative of position with respect to time.
Rate of change: The derivative measures how a quantity changes as its input changes.
Additional info:
These notes cover the foundational topics in Calculus I, including numbers, functions, limits, continuity, and the basics of differentiation, as outlined in the course contents.
