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MATHEMATICAL TRIPOS Part IA Thursday 29 May 2008 9.00 to 12.00 PAPER 1 Before you begin read these instructions carefully. The examination paper is divided into two sections. Each question in Section II carries twice the number of marks of each question in Section I. Candidates may attempt all four questions from Section I and at most five questions from Section II. In Section II, no more than three questions on each course may be attempted. Complete answers are preferred to fragments. Write on one side of the paper only and begin each answer on a separate sheet. Write legibly; otherwise you place yourself at a grave disadvantage. At the end of the examination: Tie up your answers in separate bundles, marked A, B, C, D, E and F according to the code letter affixed to each question. Include in the same bundle all questions from Section I and II with the same code letter. Attach a gold cover sheet to each bundle; write the code letter in the box marked EXAMINER LETTER on the cover sheet. You must also complete a green master cover sheet listing all the questions you have attempted. Every cover sheet must bear your examination number and desk number. STATIONERY REQUIREMENTS Gold cover sheets Green master cover sheet SPECIAL REQUIREMENTS None You may not start to read the questions printed on the subsequent pages until instructed to do so by the Invigilator.

2 SECTION I 1B State de Moivre s Theorem. By evaluating n e irθ, r=1 or otherwise, show that n cos (rθ) = r=1 cos (nθ) cos ((n + 1)θ) 2 (1 cos θ) 1 2. Hence show that n ( ) 2 p π r cos = 1, n + 1 r=1 where p is an integer in the range 1 p n. 2A Let U be an n n unitary matrix (U U = UU = I). Suppose that A and B are n n Hermitian matrices such that U = A + ib. Show that (i) A and B commute, (ii) A 2 + B 2 = I. Find A and B in terms of U and U, and hence show that A and B are uniquely determined for a given U.

3 3F Analysis I State the ratio test for the convergence of a series. Find all real numbers x such that the series n=1 x n 1 n converges. 4E Analysis I Let f : [0, 1] R be Riemann integrable, and for 0 x 1 set F (x) = x f(t) dt. 0 Assuming that f is continuous, prove that for every 0 < x < 1 the function F is differentiable at x, with F (x) = f(x). If we do not assume that f is continuous, must it still be true that F is differentiable at every 0 < x < 1? Justify your answer. [TURN OVER

4 SECTION II 5B (a) Use suffix notation to prove that Hence, or otherwise, expand (i) (a b) (c d), (ii) (a b) [(b c) (c a)]. a (b c) = (a c) b (a b) c. (b) Write down the equation of the line that passes through the point a and is parallel to the unit vector ˆt. The lines L 1 and L 2 in three dimensions pass through a 1 and a 2 respectively and are parallel to the unit vectors ˆt 1 and ˆt 2 respectively. Show that a necessary condition for L 1 and L 2 to intersect is (a 1 a 2 ) (ˆt 1 ˆt 2 ) = 0. Why is this condition not sufficient? In the case in which L 1 and L 2 are non-parallel and non-intersecting, find an expression for the shortest distance between them.

5 6A A real 3 3 matrix A with elements A ij is said to be upper triangular if A ij = 0 whenever i > j. Prove that if A and B are upper triangular 3 3 real matrices then so is the matrix product AB. Consider the matrix A = 1 2 0 0 1 1. 0 0 1 Show that A 3 + A 2 A = I. Write A 1 as a linear combination of A 2, A and I and hence compute A 1 explicitly. For all integers n (including negative integers), prove that there exist coefficients α n, β n and γ n such that A n = α n A 2 + β n A + γ n I. For all integers n (including negative integers), show that (A n ) 11 = 1, (A n ) 22 = ( 1) n, and (A n ) 23 = n ( 1) n 1. Hence derive a set of 3 simultaneous equations for {α n, β n, γ n } and find their solution. [TURN OVER

6 7C Prove that any n orthonormal vectors in R n form a basis for R n. Let A be a real symmetric n n matrix with n orthonormal eigenvectors e i and corresponding eigenvalues λ i. Obtain coefficients a i such that x = i a i e i is a solution to the equation Ax µx = f, where f is a given vector and µ is a given scalar that is not an eigenvalue of A. How would your answer differ if µ = λ 1? Find a i and hence x when in the cases (i) µ = 2 and (ii) µ = 1. A = 2 1 0 1 2 0 and f = 1 2 0 0 3 3 8C Prove that the eigenvalues of a Hermitian matrix are real and that eigenvectors corresponding to distinct eigenvalues are orthogonal (i.e. e i e j = 0). Let A be a real 3 3 non-zero antisymmetric matrix. Show that ia is Hermitian. Hence show that there exists a (complex) eigenvector e 1 such Ae 1 = λe 1, where λ is imaginary. Show further that there exist real vectors u and v and a real number θ such that Au = θv and Av = θu. Show also that A has a real eigenvector e 3 such that Ae 3 = 0. Let R = I + n=1 R is a rotation matrix. A n n!. By considering the action of R on u, v and e 3, show that

7 9F Analysis I Investigate the convergence of the series (i) (ii) n=2 n=3 1 n p (log n) q 1 n (log log n) r for positive real values of p, q and r. [You may assume that for any positive real value of α, log n < n α for n sufficiently large. You may assume standard tests for convergence, provided that they are clearly stated.] 10D Analysis I (a) State and prove the intermediate value theorem. (b) An interval is a subset I of R with the property that if x and y belong to I and x < z < y then z also belongs to I. Prove that if I is an interval and f is a continuous function from I to R then f(i) is an interval. (c) For each of the following three pairs (I, J) of intervals, either exhibit a continuous function f from I to R such that f(i) = J or explain briefly why no such continuous function exists: (i) I = [0, 1], J = [0, ) ; (ii) I = (0, 1], J = [0, ) ; (iii) I = (0, 1], J = (, ). [TURN OVER

8 11D Analysis I (a) Let f and g be functions from R to R and suppose that both f and g are differentiable at the real number x. Prove that the product fg is also differentiable at x. (b) Let f be a continuous function from R to R and let g(x) = x 2 f(x) for every x. Prove that g is differentiable at x if and only if either x = 0 or f is differentiable at x. (c) Now let f be any continuous function from R to R and let g(x) = f(x) 2 for every x. Prove that g is differentiable at x if and only if at least one of the following two possibilities occurs: (i) f is differentiable at x; (ii) f(x) = 0 and f(x + h) h 1/2 0 as h 0. 12E Analysis I Let n=0 a nz n be a complex power series. Prove that there exists an R [0, ] such that the series converges for every z with z < R and diverges for every z with z > R. Find the value of R for each of the following power series: 1 (i) n 2 zn ; n=1 (ii) z n!. n=0 In each case, determine at which points on the circle z = R the series converges. END OF PAPER

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