Trigonometric formulas

Learning Objectives • Solve integration problems involving products and powers of \(\sin x\) and \(\cos x\). • Solve integration problems involving products and powers of \(\tan x\) and \(\sec x\). • Use reduction formulas to solve trigonometric integrals. In this section we look at how to integrate a variety of products of trigonometric functions. These integrals are called trigonometric integrals. They are an important part of the integration technique called trigonometric substitution, which is featured in Trigonometric Substitution. This technique allows us to convert algebraic expressions that we may not be able to integrate into expressions involving trigonometric functions, which we may be able to integrate using the techniques described in this section. In addition, these types of integrals appear frequently when we study polar, cylindrical, and spherical coordinate systems later. Let’s begin our study with products of \(\sin x\) and \(\cos x.\) Integrating Products and Powers of sin x and cos x A key idea behind the strategy used to integrate combinations of products and powers of \(\sin x\) and \(\cos x\) involves rewriting these expressions as sums and differences of integrals of the form \(∫\sin^jx\cos x\,dx\) or \(∫\cos^jx\sin x\,dx\). After rewriting these integrals, we evaluate them using \(u\)-substitution. Before describing the general process in detail, let’s take a look at the following examples. Example \(\PageIndex\cos^4x+C.\nonumber \] Exercise \(\Pag...

Learning Objectives • Solve integration problems involving products and powers of \(\sin x\) and \(\cos x\). • Solve integration problems involving products and powers of \(\tan x\) and \(\sec x\). • Use reduction formulas to solve trigonometric integrals. In this section we look at how to integrate a variety of products of trigonometric functions. These integrals are called trigonometric integrals. They are an important part of the integration technique called trigonometric substitution, which is featured in Trigonometric Substitution. This technique allows us to convert algebraic expressions that we may not be able to integrate into expressions involving trigonometric functions, which we may be able to integrate using the techniques described in this section. In addition, these types of integrals appear frequently when we study polar, cylindrical, and spherical coordinate systems later. Let’s begin our study with products of \(\sin x\) and \(\cos x.\) Integrating Products and Powers of sin x and cos x A key idea behind the strategy used to integrate combinations of products and powers of \(\sin x\) and \(\cos x\) involves rewriting these expressions as sums and differences of integrals of the form \(∫\sin^jx\cos x\,dx\) or \(∫\cos^jx\sin x\,dx\). After rewriting these integrals, we evaluate them using \(u\)-substitution. Before describing the general process in detail, let’s take a look at the following examples. Example \(\PageIndex\cos^4x+C.\nonumber \] Exercise \(\Pag...