← 2017 Paper 2
UPSC 2017 Maths Optional Paper 2 Q4a — Step-by-Step Solution
15 marks · Section A
Taylor's Series for Analytic Functions · Complex Analysis · Read the full method →
Question
For a function f:C→C and n≥1, let f(n) denote the nth derivative of f and f(0)=f. Let f be an entire function such that for some n≥1, f(n)(k1)=0 for all k=1,2,3,…. Show that f is a polynomial.
Technique
Derivatives of entire functions are entire; Identity Theorem on f(n) using the accumulation point 0 of {1/k}; then f(n)≡0⇒f polynomial of degree <n.
Solution
The strategy: derivatives of an entire function are entire, so f(n) is entire; it vanishes on a set with an accumulation point, hence is identically zero by the Identity Theorem; an entire function whose nth derivative is 0 is a polynomial of degree <n.
Step 1 — f(n) is entire
Since f is entire (analytic on all of C), it is infinitely complex-differentiable, and every derivative of an analytic function is again analytic. In particular g:=f(n) is entire.
Step 2 — The zero set has an accumulation point in C
By hypothesis g(k1)=f(n)(k1)=0 for all k=1,2,3,…. The points zk=k1 are distinct, lie in C, and satisfy
zk=k1⟶0(k→∞).
So the zero set {zk} has the accumulation point 0, and crucially 0∈C — it is in the domain C on which g is analytic. (By continuity g(0)=limkg(1/k)=0 too, so 0 is itself a zero, but the accumulation is the key point.)
Step 3 — Identity Theorem ⇒g≡0
Identity Theorem. If a function analytic on a connected open set has zeros accumulating at a point inside that set, then it is identically zero there.
C is connected and open; g=f(n) is analytic on it; its zeros {1/k} accumulate at 0∈C. Therefore
f(n)(z)≡0for all z∈C.
Step 4 — f(n)≡0 forces f to be a polynomial of degree <n
Integrating n times: f(n)≡0 gives f(n−1)≡cn−1 (constant), then f(n−2)(z)=cn−1z+cn−2, and inductively f is a polynomial of degree at most n−1. (Equivalently, in the Taylor expansion f(z)=∑m≥0amzm, we have f(n)(z)=∑m≥n(m−n)!m!amzm−n≡0, which forces am=0 for all m≥n.)
Hence f is a polynomial:
Answer
f(n)(k1)=0 ∀k ⟹ f(n)≡0 ⟹ f is a polynomial of degree≤n−1.