SAT Integration Definition, Formulas, and Methods with Solved Examples

Integration an Inverse Process of Differentiation

Given a function's derivative, our task is to determine its primitive, which refers to the original function. This procedure is known as anti-differentiation or integration. When we possess the derivative of a function, the act of uncovering the original function is called integration. Derivatives and integrals exhibit an inverse relationship. 

Let's consider the function . The derivative of is denoted as . We refer to as the derived function of , while is recognized as the anti-derivative of .

Rules of Integration

We are already acquainted with the derivative formulas for several significant functions. Now, let's explore the corresponding standard integrals or integration formulas for these functions.

Certain rules have been established for the computation of integrals, encompassing the following:

Sum and Difference Rules:

• .
• .

Power Rule:

• , where .

Exponential Rules:

• .
• .
• .

Constant Multiplication Rule:

• , where is the constant.

Reciprocal Rule:

• .

Properties of Integration

Integration exhibits several properties that aid in the computation and manipulation of integrals. These properties include:

• The integral of the sum or difference of two functions, and , is equal to the sum or difference of their individual integrals: .
• The integral of a constant times a function, , is equal to the constant multiplied by the integral of the function: , where is any real number.
• If the integral of the difference between two functions, and , is equal to zero, then the integrals of and are equal: implies .
• The combination of the first two properties leads to: . In this form, the integral of a linear combination of multiple functions is equal to the linear combination of their individual integrals, where are real numbers.

These properties of integration serve as fundamental tools for solving integrals and manipulating expressions involving integrals, allowing for efficient and accurate computations.

Methods of Integration

In certain cases, mere inspection may not suffice to determine the integral of certain functions. However, there exist additional techniques that aid in transforming functions into standard forms, facilitating the computation of their integrals. The following methods are prominent and will be explored in detail.

The methods of integration are:

• Decomposition method
• Integration by Substitution
• Integration using Partial Fractions
• Integration by Parts

Method 1: Integration by Decomposition

The given functions can be expressed as a combination of algebraic, trigonometric, or exponential functions, or a combination thereof, which can be further decomposed into a sum or difference of functions. The integrals of these individual functions are already known or can be evaluated using established techniques.

When faced with the task of integrating , we can break down the function into its constituent parts in the following manner:

Applying the reciprocal rule and the power rule, we get

Method 2: Integration by Substitution

The method of substitution in integration enables us to introduce a new variable of integration, allowing for a simpler integration of the integrand.

Suppose, we have to find .

Let . Then,

So, dx can be written as

For example, let's find the integral of using substitution.

Let . Then,

\(= -\frac{1}{m}\cos(mx) + C)

So, can be written as

Note: It is worth mentioning that trigonometric identities can also be utilized as substitutions for the variable of integration. There are several significant standard results in this regard, including:

Method 3: Integration Using Partial Fractions

Integration using partial fractions is a technique used to simplify and evaluate integrals of rational functions by decomposing them into simpler fractions. The process involves the following steps:

Step 1: Factorize the denominator of the rational function into irreducible factors.

Step 2: Express the rational function as a sum of partial fractions, where each fraction has a simpler denominator than the original.

Step 3: Determine the unknown constants in the partial fractions by equating the coefficients of corresponding terms.

Step 4: Integrate each partial fraction separately using standard integration techniques.

Step 5: Combine the integrals of the partial fractions to obtain the final solution.

Integration using partial fractions is especially useful when dealing with rational functions that are difficult to integrate directly. By breaking them down into simpler fractions, we can simplify the integration process and obtain the solution more easily.

Below is a table displaying various rational functions alongside their corresponding partial fraction forms.

Method 4: Integration By Parts

Integration by parts is a powerful technique used to integrate the product of two functions. It is based on the product rule for differentiation and involves the following steps: 

Step 1 (Identify the functions): Split the integrand into two functions, typically denoted as and .

Step 2 (Assign variables): Choose which function, or , to differentiate and which one to integrate. This choice is often guided by a priority order known as "LIATE" (Logarithmic, Inverse trigonometric, Algebraic, Trigonometric, Exponential). 

Step 3 (Apply the integration by parts formula): The integration by parts formula is given by: . Here, and are the chosen functions, and and represent their respective differentials.

Step 4 (Calculate differentials): Take the derivative of and integrate with respect to the variable of integration.

Step 5 (Simplify the integral): Substitute the values of , , , and into the integration by parts formula to obtain a new integral.

Step 6 (Repeat if necessary): If the new integral is still difficult to solve, apply integration by parts again until a simpler integral is obtained.

Step 7 (Solve for the final integral): Evaluate the simplified integral using integration techniques appropriate for the remaining terms.

Step 8 (Include the constant of integration): Don't forget to add the constant of integration to the final result.

Integration by parts is particularly useful when dealing with products of functions that cannot be easily integrated by other techniques. By differentiating one function and integrating the other, we can often simplify the integrand and make it more amenable to evaluation.

A few important standard results(Bernoulli's formula):

Integration of Rational Algebraic Functions

When dealing with rational algebraic functions that have numerators and denominators containing positive integral powers of and constant coefficients, the technique of integration by partial fractions is employed. This method allows us to decompose the rational function into simpler fractions and obtain a set of standard results that can be directly applied as integration formulas.

Application of Integrations

Integration finds wide application in various fields and disciplines. Some common applications of integration include:

• Calculating Areas and Volumes: Integration enables the computation of areas under curves and volumes of solid objects. This is crucial in geometry, physics, and engineering for determining quantities such as the area of irregular shapes or the volume of complex three-dimensional objects.
• Solving Differential Equations: Integration plays a central role in solving differential equations. Many mathematical models in physics, engineering, and biology can be described using differential equations, and integration helps obtain solutions by finding antiderivatives.
• Probability and Statistics: Integration is applied in probability theory and statistics to calculate probabilities and analyze random variables. For example, the area under a probability density function curve represents the probability of an event occurring within a certain range.
• Physics and Engineering: Integration is extensively used in physics and engineering for various applications such as calculating work, energy, electric charge, magnetic flux, fluid flow, and heat transfer.
• Economics and Finance: Integration is employed in economics and finance to analyze economic models, evaluate financial derivatives, and compute measures such as consumer surplus and producer surplus.

These are just a few examples of the broad applications of integration in different fields. Integration provides a powerful tool for analyzing, modeling, and solving problems across various disciplines.

Integration Summary

• Integration is a fundamental operation in calculus that involves finding antiderivatives of functions.
• Integration is the reverse process of differentiation, where we find the original function from its derivative.
• The notation used for integration is the integral symbol () followed by the function to be integrated and a differential element (e.g., ).
• Integration is a linear operation, meaning we can split integrals over sums and scale them by constants.
• The constant of integration () accounts for the family of antiderivatives of a function.
• Integration by parts is a technique for integrating products of functions using the product rule for differentiation.
• Substitution is a powerful method for simplifying integrals by replacing variables with new expressions.
• Definite integrals are used to calculate the net area under a curve between two points.

Integration Solved Examples

1.Find the integration of and integration of .

Solution:

The integration of and can be found as follows:

Integration of cot(x):

The integral of can be evaluated using the substitution method. 

Let's substitute , then . 

The integral becomes:

,

where is the constant of integration.

Integration of log(x):

The integral of can be found using integration by parts. 

Let's choose and , then and . Applying the integration by parts formula, we have:

,

where is the constant of integration.

Therefore, the integration of is , and the integration of is .

2.Evaluate the integral .

Solution:

To integrate the given function, we apply the basic rules of integration.

,

where is the constant of integration.

3.Find the integration .

Solution:

To integrate , we apply the linearity property of integration. 

The integral of is , and the integral of is . 

Combining the results, we have:

,

where is the constant of integration.

Conclusion

To wrap it up, integration is a key concept in calculus that helps us understand areas, curves, and functions. Whether you're tackling SAT, ACT, or AP exams, mastering integration techniques and rules like the power rule and sum rule can make solving problems much easier. By learning the properties of integration and practicing different methods, you'll be equipped to handle a wide range of calculus questions with confidence.