← 2016 Paper 2
UPSC 2016 Maths Optional Paper 2 Q3c — Step-by-Step Solution
15 marks · Section A
Cauchy's residue theorem · Complex Analysis · asked 5× in 13 yrs · Read the full method →
Question
Let γ:[0,1]→C be the curve γ(t)=e2πit, 0≤t≤1. Find, giving justifications, the value of the contour integral ∫γ4z2−1dz.
Technique
Residue theorem on the unit circle; factor 4z2−1=(2z−1)(2z+1); simple-pole residues via g/h′=1/(8z); sum the (interior) residues.
Solution
γ is the unit circle ∣z∣=1 traversed once counterclockwise. We locate the poles of the integrand relative to γ, compute residues at those inside, and apply the Cauchy residue theorem.
Step 1 — Identify the contour and the singularities
γ(t)=e2πit, t∈[0,1], is the positively oriented unit circle ∣z∣=1. Factor the denominator:
4z2−1=(2z−1)(2z+1),
so the integrand f(z)=4z2−11 has simple poles at
z=21andz=−21.
Both satisfy ∣z∣=21<1, so both poles lie inside γ. (Neither lies on γ, so the integral is well defined.)
Step 2 — Residues at the simple poles
For a simple pole, Resz0h(z)g(z)=h′(z0)g(z0) with g=1, h=4z2−1, h′=8z.
z=1/2Resf=8⋅211=41,z=−1/2Resf=8⋅(−21)1=−41.
(Equivalently via partial fractions 4z2−11=z−1/21/4−z+1/21/4, the residues are the coefficients 41 and −41.)
Step 3 — Apply the residue theorem
Since f is analytic inside and on γ except at the two interior simple poles, the residue theorem gives
∫γ4z2−1dz=2πi(z=1/2Resf+z=−1/2Resf)=2πi(41−41)=2πi⋅0.
Therefore
Answer
∫γ4z2−1dz=0.