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Trigonometric Integrals

When integrating complex trigonometric functions, we often need to use a combination of substitutions and trig identities.

Case 1: sinmxcosnx  ⁣dx{\displaystyle\int} \sin^m x \cos^n x \de{x}

  • Power of sinx\sin x is odd
  • Keep a copy of sinx\sin x and convert the rest to cosx\cos x using sin2x=1cos2x\sin^2x=1-\cos^2x
  • Formula: cosnx(1cos2x)ksinx  ⁣dx{\displaystyle \int}\cos^nx(1-\cos^2x)^k\sin x\de{x}
  • Do a U-substitution with u=cosxu=\cos x
  • Power of cosx\cos x is odd
  • Keep a copy of cosx\cos x and convert the rest to sinx\sin x using cos2x=1sin2x\cos^2x=1-\sin^2x
  • Formula: sinmx(1sin2x)kcosx  ⁣dx{\displaystyle \int}\sin^mx(1-\sin^2x)^k\cos x\de{x}
  • Do a U-substitution with u=sinxu=\sin x
  • Both powers of sinx and cosx\sin x \ \text{and} \ \cos x are even
  • Convert everything into sin(...x)\sin\left(...x\right) or cos(...x)\cos\left(...x\right) using double and half angle formulas:
  • sin2x=1cos2x2\displaystyle \sin^2x=\frac{1-\cos2x}{2}
  • cos2x=1+cos2x2\displaystyle \cos^2x=\frac{1+\cos2x}{2}
  • sinxcosx=sin2x2\displaystyle \sin x\cos x=\frac{\sin2x}{2}
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Case 2: tanmxsecnx  ⁣dx{\displaystyle\int}\tan^m x\sec^nx\de{x}

  • Power of secx\sec x is even
  • Keep a copy of sec2x\sec^2x and convert the rest to tanx\tan x using sec2x=1+tan2x\sec^2x=1+\tan^2x
  • Formula: tanmx(1+tan2x)ksec2x  ⁣dx{\displaystyle \int}\tan^mx(1+\tan^2x)^k\sec^2 x\de{x}
  • Do a U-substitution with u=tanxu=\tan x
  • Power of tanx\tan x is odd
  • Keep a copy of secx tanx\sec x\ \tan x and convert the rest to secx\sec x using tan2x=sec2x1\tan^2x=\sec^2x-1
  • Formula: secn1x(sec2x1)ksecxtanx  ⁣dx{\displaystyle \int}\sec^{n-1}x(\sec^2x-1)^k\sec x\tan x\de{x}
  • Do a U-substitution with u=secxu=\sec x

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Case 3: cotmxcscnx  ⁣dx{\displaystyle\int}\cot^m x\csc^nx\de{x}

  • Power of cscx\csc x is even
  • Keep a copy of csc2x\csc^2x and convert the rest to cotx\cot x using csc2x=1+cot2x\csc^2x=1+\cot^2x
  • Formula: cotmx(1+cot2x)kcsc2x  ⁣dx{\displaystyle \int}\cot^mx(1+\cot^2x)^k\csc^2x\de{x}
  • Do a U-substitution with u=cotxu=\cot x
  • Power of cotx\cot x is odd
  • Keep a copy of cscx cotx\csc x\ \cot x and convert the rest to cscx\csc x using cot2x=csc2x1\cot^2x=\csc^2x-1
  • Formula: cscn1x(csc2x1)kcscxcotx  ⁣dx{\displaystyle \int}\csc^{n-1}x(\csc^2x-1)^k\csc x\cot x\de{x}
  • Do a U-substitution with u=cscxu=\csc x
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Case 4: sin(mx) cos(nx)   ⁣dx ,sin(mx) sin(nx)   ⁣dx,cos(mx) cos(nx)   ⁣dx{\displaystyle\int}\sin(mx)\ \cos (nx)\ \de{x} \ ,{\displaystyle\int}\sin(mx)\ \sin(nx)\ \de{x}, {\displaystyle\int}\cos(mx)\ \cos(nx)\ \de{x}

Use the identities
  • sinA cosB=12[sin(AB)+sin(A+B)]\displaystyle \sin A\ \cos B=\frac{1}{2}\left[\sin\left(A-B\right)+\sin\left(A+B\right)\right]
  • sinA sinB=12[cos(AB)cos(A+B)]\displaystyle \sin A\ \sin B=\frac{1}{2}\left[\cos\left(A-B\right)-\cos\left(A+B\right)\right]
  • cosA cosB=12[cos(AB)+cos(A+B)]\displaystyle \cos A\ \cos B=\frac{1}{2}\left[\cos\left(A-B\right)+\cos\left(A+B\right)\right]
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Example: Trig Integrals (Case 1)

Evaluate the following indefinite integral

sin4xcos3x   ⁣dx{\displaystyle\int}\sin^4x\cos^3x\space\de{x}

Keep one copy of cos and convert the rest to sin
=sin4x(cos2x) (cosx)   ⁣dx={\displaystyle\int}\sin^4x(\cos^2x)\space(\cos x)\space\de{x}
=sin4x(1sin2x)(cosx)   ⁣dx={\displaystyle\int} \sin^4x(1-\sin^2x)(\cos x) \space\de{x}

We need to do a U-substitution:

Let u=sinxu=\sin x, then   ⁣du=cosx   ⁣dx\de{u}=\cos x \space\de{x}, and dx=1cosxdu\displaystyle dx=\frac{1}{\cos x}du
The new integral becomes:
=u4(1u2)(cosx)(1cosx  ⁣du)=\displaystyle\int u^4(1-u^2)(\cos x)\left(\frac{1}{\cos x}\de{u}\right)

=u4(1u2) du\displaystyle =\int_{ }^{ }u^4\left(1-u^2\right)\ du

=(u4u6)du\displaystyle =\int_{ }^{ }\left(u^4-u^6\right)du

=u55u77+C\displaystyle =\frac{u^5}{5}-\frac{u^7}{7}+C

=sin5x5sin7x7+C\displaystyle =\frac{\sin^5x}{5}-\frac{\sin^7x}{7}+C
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Example: Trig Integrals (Case 1)

Evaluate the following indefinite integral

sin2xcos2x   ⁣dx{\displaystyle\int} \sin^2x\cos^2x\space\de{x}
Let's convert everything into cos x using the half-angle formulas:
=[1cos(2x)2][1+cos(2x)2]  ⁣dx\displaystyle ={\displaystyle\int}\left[\frac{1-\cos(2x)}{2}\right]\left[\frac{1+\cos(2x)}{2}\right]\de{x}

=1cos2(2x)22  ⁣dx\displaystyle ={\displaystyle\int}\frac{1-\cos^2(2x)}{2^2}\de{x}

=(14cos2(2x)4) dx\displaystyle ={\displaystyle \int}\left(\frac{1}{4}-\frac{\cos^2\left(2x\right)}{4}\right)\ dx

=14  ⁣dx  14cos2(2x)  ⁣dx\displaystyle ={\displaystyle\int}\frac{1}{4}\de{x}\space-\space\frac{1}{4}{\displaystyle\int}\cos^2(2x)\de{x}

Using the half-angle formula again for cos:

=14  ⁣dx  141+cos(4x)2  ⁣dx\displaystyle ={\displaystyle\int}\frac{1}{4}\de{x}\space-\space\frac{1}{4}{\displaystyle\int}\frac{1+\cos(4x)}{2}\de{x}

=14  ⁣dx  18(1+cos(4x))  ⁣dx\displaystyle ={\displaystyle\int}\frac{1}{4}\de{x}\space - \space\frac{1}{8}{\displaystyle\int}(1+\cos(4x))\de{x}

=14x  18x  sin(4x)32+C\displaystyle =\frac{1}{4}x \space- \space\frac{1}{8}x \space - \space\frac{\sin(4x)}{32}+C

=x8  sin(4x)32+C\displaystyle =\frac{x}{8} \space - \space \frac{\sin(4x)}{32}+C
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Example: Trig Integrals (Case 2)

Evaluate the following indefinite integral

sec8xtan6x   ⁣dx{\displaystyle\int}\sec^8x\tan^6x\space\de{x}
Keep a copy of sec2x\sec^2x and convert the rest to tanx\tan x:

=(sec2x)(sec6x)tan6x dx\displaystyle =\int_{ }^{ }\left(\sec^2x\right)\left(\sec^6x\right)\tan^6x\ dx
=(sec2x)(sec2x)3tan6x dx\displaystyle =\int_{ }^{ }\left(\sec^2x\right)\left(\sec^2x\right)^3\tan^6x\ dx
=(sec2x)(1+tan2x)3tan6x dx\displaystyle =\int_{ }^{ }\left(\sec^2x\right)\left(1+\tan^2x\right)^3\tan^6x\ dx

We need to do a U-substitution:

Let u=tanxu=\tan x, then   ⁣du=sec2x  ⁣dx\de{u}=\sec^2x\de{x} and dx=1sec2xdu\displaystyle dx=\frac{1}{\sec^2x}du
The new integral becomes:
=(sec2x)(1+u2)3(u6)(1sec2xdu)\displaystyle =\int_{ }^{ }\left(\sec^2x\right)\left(1+u^2\right)^3\left(u^6\right)\left(\frac{1}{\sec^2x}du\right)
=(1+u2)3 (u6) du\displaystyle =\int_{ }^{ }\left(1+u^2\right)^{3\ }\left(u^6\right)\ du
=(u6+3u4+3u2+1) u6 du\displaystyle =\int_{ }^{ }\left(u^6+3u^4+3u^2+1\right)\ u^6\ du
=(u12+3u10+3u8+u6) du\displaystyle =\int_{ }^{ }\left(u^{12}+3u^{10}+3u^8+u^6\right)\ du
=u1313+3u1111+3u99+u77+C\displaystyle =\frac{u^{13}}{13}+\frac{3u^{11}}{11}+\frac{3u^9}{9}+\frac{u^7}{7}+C
=tan13x13+3tan11x11+tan9x3+tan7x7+C\displaystyle =\frac{\tan^{13}x}{13}+\frac{3\tan^{11}x}{11}+\frac{\tan^9x}{3}+\frac{\tan^7x}{7}+C

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Example: Trig Integrals (Case 4)

Evaluate the following indefinite integral

sin(3x)sin(2x)   ⁣dx{\displaystyle \int} \sin(3x)\sin(2x)\ \de{x}

Using the appropriate identity:

sin(3x)sin(2x)   ⁣dx{\displaystyle \int} \sin(3x)\sin(2x)\ \de{x}
=12[cos(3x2x)cos(3x+2x)]  ⁣dx\displaystyle ={\displaystyle \int} \frac{1}{2}[\cos(3x-2x)-\cos(3x+2x)]\de{x}

=12[cosxcos5x]  ⁣dx\displaystyle =\frac{1}{2}{\displaystyle \int} [\cos x-\cos 5x]\de{x}

=12[sinxsinx5]+C\displaystyle =\frac{1}{2}\left[\sin x-\frac{\sin x}{5}\right]+C

=sinx2sin5x10+C\displaystyle =\frac{\sin x}{2}-\frac{\sin5x}{10}+C
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Example: Trig Integrals

Evaluate the following indefinite integral

secx dx\displaystyle \int_{ }^{ }\sec x\ dx

=(secx  secx+tanxsecx+tanx)dx\displaystyle ={\displaystyle \int}\left(\sec x\ \cdot\ \frac{\sec x+\tan x}{\sec x+\tan x}\right)dx

=(sec2x+secx tanxsecx+tanx)dx\displaystyle ={\displaystyle \int}\left(\frac{\sec^2x+\sec x\ \tan x}{\sec x+\tan x}\right)dx

We'll do a U-substitution:

Let u=secx+tanxu=\sec x+\tan x, then du=(secx tanx+sec2x)dxdu=\left(\sec x\ \tan x+\sec^2x\right)dx, and dx=1secx tanx+sec2xdu\displaystyle dx=\frac{1}{\sec x\ \tan x+\sec^2x}du
The new integral becomes:

=(sec2x+secx tanxu)(1secx tanx+sec2xdu)\displaystyle ={\displaystyle \int}\left(\frac{\sec^2x+\sec x\ \tan x}{u}\right)\left( \frac{1}{\sec x\space \tan x+\sec^2x}du\right)

=1u du\displaystyle ={\displaystyle \int}\frac{1}{u}\space du

=lnu+C\displaystyle =\ln\left|u\right|+C

=lnsecx+tanx+C=\ln\left|\sec x+\tan x\right|+C

Practice: Trig Integrals

Evaluate the following indefinite integral

cos4(x)  ⁣dx{\displaystyle \int}\cos^4(x)\de{x}

Practice: Trig Integrals

Evaluate the following indefinite integral

sin7x  ⁣dx{\displaystyle\int}\sin^7x\de{x}

Practice: Trig Integrals

Evaluate the following indefinite integral

sec6x  ⁣dx{\displaystyle\int}\sec^6x\de{x}

Practice: Trig Integrals

Evaluate the following indefinite integral

sin(15x)cos(4x)  ⁣dx{\displaystyle\int}\sin(15x)\cos(4x)\de{x}

Extra Practice