Question #0bb11
1 Answer
Explanation:
#I=int1/(3+2sin(x)-cos(x))dx#
What we will use here is the tangent half-angle substitution, also sometimes known as the Weierstrass substitution.
This substitution allows us to write functions like
First, we can derive the identities we will need. Using the sine double-angle formula, we can first write that:
#sin(2alpha)=2sin(alpha)cos(alpha)#
Which can be modified to say that:
#sin(x)=2sin(x/2)cos(x/2)#
Rearranging to make tangent "appear:"
#sin(x)=2(sin(x/2)/cos(x/2))cos^2(x/2)=2tan(x/2)(1/sec^2(x/2))#
Using the Pythagorean identity:
#sin(x)=(2tan(x/2))/(1+tan^2(x/2))" "color(red)((star)#
Using a similar process for cosine, starting with its double-angle formula adapted for sine:
#cos(2alpha)=1-2sin^2(alpha)=>cos(x)=1-2sin^2(x/2)#
Continuing on by making tangent "appear:"
#cos(x)=1-2(sin^2(x/2)/cos^2(x/2))cos^2(x/2)=1-2tan^2(x/2)(1/sec^2(x/2))#
#cos(x)=1-(2tan^2(x/2))/(1+tan^2(x/2))#
Once you find a common denominator and combine the fractions:
#cos(x)=(1-tan^2(x/2))/(1+tan^2(x/2))" "color(blue)((star)#
Substituting identities
#I=int1/(3+(4tan(x/2))/(1+tan^2(x/2))-(1-tan^2(x/2))/(1+tan^2(x/2)))dx#
Finding a common denominator:
#I=int1/((3+3tan^2(x/2))/(1+tan^2(x))+(4tan(x/2))/(1+tan^2(x/2))-(1-tan^2(x/2))/(1+tan^2(x/2)))dx#
#I=int1/((4tan^2(x/2)+4tan(x/2)+2)/(1+tan^2(x/2))dx#
#I=1/2int(1+tan^2(x/2))/(2tan^2(x/2)+2tan(x/2)+1)dx#
Now, let
#I=int(du)/(2u^2+2u+1)=1/2int(du)/(u^2+u+1/2)#
Completing the square gives:
#I=1/2int(du)/((u+1/2)^2+1/4)#
Now, we can treat this like a trig substitution and let
#I=1/2int(1/2sec^2(theta)d theta)/((1/2tan(theta))^2+1/4)#
#I=1/4int(sec^2(theta)d theta)/(1/4tan^2(theta)+1/4)#
#I=1/4int(4sec^2(theta)d theta)/(tan^2(theta)+1)#
Since
#I=int(sec^2(theta)d theta)/sec^2(theta)=intd theta=theta+C#
From
#I=arctan(2u+1)+C#
Since
#I=arctan(2tan(x/2)+1)+C#
