Glossary

19.1 Definition and basic antiderivatives

3 min readjuly 22, 2024

Antiderivatives and indefinite integrals are like reverse engineering for functions. Instead of finding how fast something changes, we figure out what function could have led to that rate of change. It's like working backwards from speed to distance.

This process is crucial for solving real-world problems. By understanding antiderivatives, we can predict future values, calculate total changes, and solve complex equations in physics, economics, and engineering.

Antiderivatives and Indefinite Integrals

Antiderivatives and derivatives relationship

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  • An of a function f(x)f(x) is a function F(x)F(x) whose derivative is f(x)f(x)
    • If F(x)=f(x)F'(x) = f(x), then F(x)F(x) is an antiderivative of f(x)f(x)
    • Example: If f(x)=2xf(x) = 2x, then F(x)=x2+CF(x) = x^2 + C is an antiderivative of f(x)f(x) because F(x)=2xF'(x) = 2x
  • The process of finding an antiderivative is the opposite of finding a derivative
    • Derivatives calculate the rate of change of a function (f(x)f'(x) represents the slope of the tangent line at each point)
    • Antiderivatives determine a function given its rate of change (F(x)F(x) represents the original function, given the derivative f(x)f(x))

Antiderivatives of basic functions

  • Power rule: If f(x)=xnf(x) = x^n, then an antiderivative of f(x)f(x) is F(x)=xn+1n+1+CF(x) = \frac{x^{n+1}}{n+1} + C, where CC is a constant and n1n \neq -1
    • Example: An antiderivative of f(x)=x3f(x) = x^3 is F(x)=x44+CF(x) = \frac{x^4}{4} + C
    • Example: An antiderivative of f(x)=xf(x) = \sqrt{x} (or x12x^{\frac{1}{2}}) is F(x)=23x32+CF(x) = \frac{2}{3}x^{\frac{3}{2}} + C
  • : If f(x)=exf(x) = e^x, then an antiderivative of f(x)f(x) is F(x)=ex+CF(x) = e^x + C
    • Example: An antiderivative of f(x)=3exf(x) = 3e^x is F(x)=3ex+CF(x) = 3e^x + C
  • :
    • If f(x)=sin(x)f(x) = \sin(x), then an antiderivative of f(x)f(x) is F(x)=cos(x)+CF(x) = -\cos(x) + C
    • If f(x)=cos(x)f(x) = \cos(x), then an antiderivative of f(x)f(x) is F(x)=sin(x)+CF(x) = \sin(x) + C
    • If f(x)=sec2(x)f(x) = \sec^2(x), then an antiderivative of f(x)f(x) is F(x)=tan(x)+CF(x) = \tan(x) + C
    • Example: An antiderivative of f(x)=2sin(x)f(x) = 2\sin(x) is F(x)=2cos(x)+CF(x) = -2\cos(x) + C

Rules for complex antiderivatives

  • : If F(x)F(x) is an antiderivative of f(x)f(x), then kF(x)kF(x) is an antiderivative of kf(x)kf(x), where kk is a constant
    • Example: If an antiderivative of f(x)=x2f(x) = x^2 is F(x)=x33+CF(x) = \frac{x^3}{3} + C, then an antiderivative of 3x23x^2 is 3(x33+C)=x3+C3(\frac{x^3}{3} + C) = x^3 + C
    • Example: If an antiderivative of f(x)=sin(x)f(x) = \sin(x) is F(x)=cos(x)+CF(x) = -\cos(x) + C, then an antiderivative of 5sin(x)5\sin(x) is 5cos(x)+C-5\cos(x) + C
  • : If F(x)F(x) is an antiderivative of f(x)f(x) and G(x)G(x) is an antiderivative of g(x)g(x), then F(x)+G(x)F(x) + G(x) is an antiderivative of f(x)+g(x)f(x) + g(x)
    • Example: If an antiderivative of f(x)=x2f(x) = x^2 is F(x)=x33+CF(x) = \frac{x^3}{3} + C and an antiderivative of g(x)=sin(x)g(x) = \sin(x) is G(x)=cos(x)+CG(x) = -\cos(x) + C, then an antiderivative of x2+sin(x)x^2 + \sin(x) is x33cos(x)+C\frac{x^3}{3} - \cos(x) + C
    • Example: An antiderivative of f(x)=x3+exf(x) = x^3 + e^x is F(x)=x44+ex+CF(x) = \frac{x^4}{4} + e^x + C

Concept of indefinite integrals

  • An is the set of all antiderivatives of a given function
    • The indefinite integral of f(x)f(x) is denoted as f(x)dx\int f(x) \, dx
    • The variable of integration (usually xx) is written as dxdx to indicate the variable with respect to which the integration is performed
    • Example: x2dx\int x^2 \, dx represents the set of all antiderivatives of x2x^2
  • The result of an indefinite integral includes a constant of integration, typically denoted as CC
    • Example: x2dx=x33+C\int x^2 \, dx = \frac{x^3}{3} + C, where CC is an arbitrary constant
    • Example: exdx=ex+C\int e^x \, dx = e^x + C
  • The constant of integration represents a family of functions that differ by a constant value
    • The specific value of CC is determined by initial conditions or boundary conditions when solving problems involving definite integrals or differential equations
    • Example: If f(x)dx=F(x)+C\int f(x) \, dx = F(x) + C and F(1)=3F(1) = 3, then C=3F(1)C = 3 - F(1)

Key Terms to Review (18)

: The symbol ∫ represents the integral in calculus, which is a fundamental concept that allows us to find the area under a curve. Integrals are closely related to antiderivatives, as they can be thought of as the reverse process of differentiation. When we calculate an integral, we are essentially summing up infinitely small pieces to determine the total accumulation of a quantity, such as area, volume, or even displacement.
Antiderivative: An antiderivative is a function whose derivative gives back the original function. It represents the process of reversing differentiation, allowing us to find the original function from its rate of change. This concept is central to understanding the relationship between differentiation and integration, which plays a vital role in various mathematical applications.
Area under a curve: The area under a curve refers to the total region enclosed between the curve of a function and the x-axis, which can be calculated using integration. This concept is crucial for understanding how functions behave over an interval and is foundational in connecting the geometric representation of a function with its analytical properties. By calculating the area under a curve, you can derive useful information about the function, such as total accumulated quantities and average values.
C for constant of integration: The constant of integration, denoted as 'c', represents an arbitrary constant added to the antiderivative of a function. This term is crucial because it accounts for the fact that differentiation removes any constant value, meaning that any two functions that differ only by a constant will have the same derivative.
Constant Multiple Rule: The constant multiple rule states that the derivative of a constant multiplied by a function is equal to the constant multiplied by the derivative of that function. This rule is fundamental in calculus as it allows for simplification when taking derivatives, making it easier to analyze and understand functions across various contexts.
Differentiation: Differentiation is the process of finding the derivative of a function, which measures how a function changes as its input changes. It provides insights into the rate of change and helps to understand various concepts such as slopes of tangent lines, rates of change in related quantities, and finding maximum or minimum values. This fundamental tool in calculus is essential for analyzing and interpreting mathematical relationships across various contexts.
Exponential rule: The exponential rule is a fundamental principle in calculus used to differentiate functions of the form $$f(x) = a^x$$, where $$a$$ is a constant and $$x$$ is the variable. This rule states that the derivative of such functions is proportional to the function itself, specifically given by $$f'(x) = a^x \ln(a)$$. Understanding this rule is crucial for solving problems involving exponential growth and decay, as well as for working with logarithmic functions.
Fundamental theorem of calculus: The fundamental theorem of calculus establishes the connection between differentiation and integration, showing that they are essentially inverse processes. This theorem consists of two parts: the first part guarantees that if a function is continuous on a closed interval, then its definite integral can be computed using its antiderivative. The second part states that the derivative of the integral of a function is equal to the original function. This fundamental concept links the concepts of derivatives and antiderivatives together, playing a crucial role in understanding how these processes relate to one another.
Indefinite integral: An indefinite integral is a function that represents the antiderivative of a given function, essentially reversing the process of differentiation. It is expressed using the integral sign and includes a constant of integration, usually denoted as '+ C', to account for the fact that there are infinitely many antiderivatives differing only by a constant. This concept is crucial for understanding how to find original functions from their rates of change, connecting directly to essential mathematical operations.
Initial Value Problems: Initial value problems are a type of differential equation that require not only the solution of the equation itself but also the determination of a specific value at a given point. This condition helps to ensure that there is a unique solution to the differential equation, as it effectively specifies an initial state. These problems are fundamental in many areas of applied mathematics, where understanding the behavior of functions over time is crucial.
Integration by Parts: Integration by parts is a technique used to integrate products of functions by transforming the integral of a product into simpler integrals. This method is based on the product rule for differentiation and helps to break down complicated integrals into manageable parts, making it easier to find antiderivatives. It involves choosing one function to differentiate and another to integrate, leading to an application that can simplify the overall calculation of antiderivatives.
Integration by substitution: Integration by substitution is a technique used to simplify the process of finding antiderivatives by substituting a variable or function in place of the original variable. This method often makes integrals easier to solve by transforming them into a more recognizable or manageable form, which is crucial when dealing with complex functions.
Linearity of Integration: The linearity of integration refers to a fundamental property of definite and indefinite integrals that states if you have two functions, the integral of their sum is equal to the sum of their integrals, and a constant can be factored out of the integral. This property simplifies the process of finding integrals by allowing the integration of each function separately before combining results. Understanding this concept is crucial for working with antiderivatives and helps in breaking down complex integrals into manageable parts.
Power Rule for Integration: The Power Rule for Integration states that for any real number $n \neq -1$, the integral of $x^n$ with respect to $x$ is given by $$\int x^n \, dx = \frac{x^{n+1}}{n+1} + C$$ where $C$ is the constant of integration. This rule simplifies the process of finding antiderivatives for polynomial functions, allowing for straightforward calculations and applications in various mathematical contexts.
Reverse process: In calculus, the reverse process refers to the action of finding antiderivatives or integrals from derivatives. This concept is vital because it allows one to go backwards in the differentiation process, recovering original functions from their rates of change. Understanding this connection is essential for solving problems involving areas under curves, accumulation of quantities, and solving differential equations.
Substitution Method: The substitution method is a technique used to find antiderivatives by substituting a new variable for a function of the original variable. This method simplifies the process of integration, particularly when dealing with composite functions. By transforming a complicated integral into a simpler one, it allows for easier calculations and understanding of the underlying relationships within functions.
Sum Rule: The Sum Rule is a fundamental principle in calculus that states the derivative of the sum of two functions is equal to the sum of their derivatives. This rule simplifies the process of differentiation by allowing us to break down complex expressions into manageable parts. It plays a crucial role in both differentiation and integration, connecting concepts of basic derivatives and antiderivatives.
Trigonometric rules: Trigonometric rules refer to the established relationships and formulas that connect the angles and sides of triangles, particularly in the context of right triangles and the unit circle. These rules help in solving problems involving angles and distances, especially when it comes to finding unknown values or simplifying complex expressions. They form a fundamental part of calculus, aiding in the integration and differentiation of trigonometric functions.
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