Calculus II: Integration and trigonometric substitutions

Some integrands, mainly that contain radicals, are easily transformed into trigonometric expressions simple to integrate.

1. Trigonometric substitutions

The trigonometric identities:

cos²(x) = 1 - sin²(x)
sec²(x) = 1 + tan²(x)
tan²(x) = sec²(x) - 1

are used, by substituting cos(x), sec(x), or tan(x), to eliminate radicals from integrals.

Sine-substitution x = a sin(θ) is used for an expression as [a² - x²]^1/2

Tangent-substitution x = a tan(θ) is used for an expression as [a² + x²]^1/2

Secant-substitution x = a sec(θ) is used for an expression as [x² - a²]^1/2

2. Sine-substitution

The integrand of the form :

f(x) = [a² - x²]^1/2,
is transformed into:

f(x) = a [1 - (x/a)²]^1/2.

Then, we make the substitution

x/a = sin θ

So

dx = a cos θ dθ

Therefore

I = ∫ f(x) dx = ∫ [a² - x²]^1/2 dx =
a ∫[1 - (x/a)²]^1/2 dx =
a² ∫[1 - sin² θ]^1/2 cos θ dθ =
a² ∫ cos²θ dθ =

Using the identity:
cos²z = (1 + cos (2z))/2

I = (a²/2) ∫ [1 + cos (2θ)] dθ =
(a²/2)[ ∫ dθ + ∫ cos (2θ) dθ ] =
(a²/2)[ θ + (1/2) sin (2θ) ] =
∫ [a² - x²]^1/2 dx =
(a²/2)[ θ + (1/2) sin (2θ) ] =
(a²/2)[ arcsin(x/a) + (1/2) sin (2θ)]

Since:
sin (2θ) = 2 sin (θ) cos(θ)

I = (a²/2)[ arcsin(x/a) + sin (θ) cos(θ)]
= (a²/2)[ arcsin(x/a) + (x/a)[1- (x/a)²]^1/2 ]

Finally,

∫ [a² - x²]^1/2 dx =
(a²/2)[ arcsin(x/a) + (x/a)[1- (x/a)²]^1/2] + cst.

3. Tangent-substitution

The the integrand of the form :

f(x) = [a² + x²]^1/2,
is transformed into:

f(x) = a [1 + (x/a)²]^1/2.

Then, we make the substitution

x/a = tan θ

So

dx = a (1 + tan²θ) dθ = a sec²θ dθ

Therefore

I = ∫ f(x) dx = ∫ [a² + x²]^1/2 dx =
a ∫[1 + (x/a)²]^1/2 dx =
a² ∫[1 + tan² θ]^1/2 sec²θ dθ =

a² ∫ sec³θ dθ =
a² [(1/2) sec x tan x + (1/2) ln |sec x + tan x|] + const.

4. Secant-substitution

The the integrand of the form :

f(x) = [x² - a² ]^1/2,
is transformed into:

f(x) = a [(x/a)²- 1]^1/2.

Then, we make the substitution

x = a sec(θ)

So

dx = a sin θ sec²θ dθ

Therefore

S = ∫ f(x) dx = ∫ [x² - a²]^1/2 dx =
a ∫[(x/a)² - 1]^1/2 dx =
a² ∫[sec²θ - 1]^1/2 sin θ sec²θ dθ =

a² ∫ tan θ sin θ sec²θ dθ =

a² ∫ sin² θ sec³θ dθ =

a² ∫ [1 - cos² θ] sec³θ dθ =

a² [∫ sec³θ dθ - ∫ cos²θ sec³θ dθ] =

a² [∫ sec³θ dθ - ∫ sec θ dθ] =

∫ sec³θ dθ =
(1/2) sec(θ). tan(θ) + (1/2)ln|(sec(θ) + tan(θ))| + cst

∫ sec θ dθ] = ln|(sec(θ) + tan(θ))| + cst

(These two integrals are calculated here.)

Therefore

S = a² [(1/2) sec(θ). tan(θ) + (1/2)ln|(sec(θ) + tan(θ))| + cst
- ln|(sec(θ) + tan(θ))| ] =

(a² /2)[sec(θ). tan(θ) - ln|sec(θ) + tan(θ)|] + cst. =

5. Other forms with radical

5.1. Example 1

∫ [ax + b]^1/n dx

Let

u = [ax + b]^1/n, so
du = a (1/n) [ax + b]^{1/n - 1} dx

Therefore

∫ [ax + b]^1/n dx =
∫ (n/a) u du [ax + b]^{1 - 1/n} =
∫ (n/a) u du uⁿ/u =
∫ (n/a) du uⁿ =
[n/a(n + 1)] u^{n + 1}

Thus

∫ [ax + b]^1/n dx = [n/a(n + 1)] u^{n + 1}

5.2. Example 2

∫ x²[1 - x]^1/2 dx

Let u = [1 - x]^1/2, so

u² = 1 - x

Then

x = 1 - u² , and dx = - 2 u du

Therefore

∫ x²[1 - x]^1/2 dx =
∫ (1 - u²)² u (- 2 u ) du =
- 2 ∫ (u² - 2 u⁴ + u⁶) du
= - 2 [(1/3)u³ - (2/5)u⁵ + (1/7)u⁷ ] + cst.

= - 2 [(1/3)[1 - x]^3/2 - (2/5)[1 - x]^5/25 + (1/7)[1 - x]^7/2 ] + cst.

∫ x²[1 - x]^1/2 dx
= (- 2/3)(1 - x)^3/2 + (4/5)(1 - x)^5/2 -
(2/7)(1 - x)^7/2 + cst.

5.3. Example 3

∫ x³[1 - x²]^1/2 dx

Let u = [1 - x²]^1/2, so

u² = 1 - x²

Then

x² = 1 - u² , and 2 x dx = - 2 u du or x dx = - u du

Therefore

∫ x³[1 - x²]^1/2 dx =
∫ x²[1 - x²]^1/2 x dx =
∫(1 - u²)u (- u) du =
- ∫(u² - u⁴) du =
= - [(1/3)u³ - (1/5)u⁵]
(1/5)u⁵ - (1/3)u³ =
(1/5)[1 - x²]^5/2 - (1/3)[1 - x²]^3/2 + cst.

∫ x³[1 - x²]^1/2 dx
= (1/5)(1 - x²)^5/2 - (1/3)(1 - x²)^3/2 + cst.