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Problem Solving (MA2201) Week 2 Timothy Murphy 1. Find the largest positive integer such that n3 + 100 is divisible by n + 10. Answer: Let N = n + 10. Then n3 + 100 = 0modN. But n = −10 mod N, so n3 + 100 = −900modN. Thus N | 900. 2. Find all positive integers n such that n! + 5 is a perfect cube. Answer: For any prime p, n! + 5 ≡ 5 mod p for all n ≥ p. So if n! + 5 is a perfect cube, then 5 is a cubic residue modp Recall that (Z/p)× is a cyclic group of order p − 1. If 3 - p − 1 then the homomorphism x 7→ x3 : (Z/p)× → (Z/p)× has trivial kernel, and so is surjective, ie every element is a cubic residue. But if 3 | p − 1 then the kernel contains just 3 elements (the elements of order 3), and so (p − 1)/3 elements are cubic residues, so there is a reasonable chance the 5 will not be. Take p = 7. There are 6/3 = 2 cubic residues, namely ±1 mod p. So 5 is not a cubic residue mod 7, and it follows that n! + 5 cannot be a cube if n ≥ 7. Checking n! + 5 for n < 7 we see that the only cube occurs when n = 5. 3. Show that the product of 4 successive integers cannot be a perfect square. Answer: Method 1 Let the successive integers be n, n + 1, n + 2, n + 3. We have n(n + 3) = n2 + 3n, (n + 1)(n + 2) = n2 + 3n + 2. Thus n(n + 3) < (n + 1)(n + 2), and so [n(n + 3)]2 < n(n + 1)(n + 2)(n + 3) < [(n + 1)(n2 )]2 . Also (n + 1)(n + 2) = n(n + 3) + 2. Thus if n(n + 1)(n + 2)(n + 3) is a perfect square, we must have n(n + 1)(n + 2)(n + 3) = [n(n + 3) + 1]2 / But that is impossible, since the left-hand side is even while the right-hand side is odd, since one of n, n + 3 is even. Method 2 Suppose n(n + 1)(n + 2)(n + 3) is a perfect square. Suppose first that 3 - n. Two of the numbers are even, and two are odd. Suppose n, n + 2 are even. Then gcd(n, n + 1) = 1, gcd(n, n + 2) = 2, gcd(n, n + 3) = 1, gcd(n + 1, n + 2) It follows that n = 2a2 , n + 1 = b2 , n + 2 = 2c2 , n + 3 = d2 . But then b2 < n + 3 < (b + 1)2 = n + 2 + 2b. So n + 2 cannot be a square (unless b = 0). In the same way, if n + 1, n + 3 are even then n = a2 , n + 1 = 2b2 , n + 2 = c2 , n + 3 = 2d2 . Again, a2 < n + 2 < (a + 1)2 . Now suppose 3 | n. Then 3 | n, n + 3. Suppose n, n + 2 are even. Then gcd(n, n + 1) = 1, gcd(n, n + 2) = 2, gcd(n, n + 3) = 3, gcd(n + 1, n + 2) It follows that n = 6a2 , n + 1 = b2 , n + 2 = 2c2 , n + 3 = 3d2 . Can we go on from here? 4. Find the positive integer n for which [log2 1] + [log2 2] + [log2 3] + · · · + [log2 n] = 2010, where [x] denotes the greatest integer ≤ x. Answer: Let N (n) = [log2 1] + [log2 2] + [log2 3] + · · · + [log2 n]. We have [log r] = 0 if r = 1 [log r] = 1 if r = 2, 3 [log r] = 2 if 4 ≤ r < 8 ... [log r] = e − 1 if 2e−1 ≤ r < 2e . Hence N (2e − 1) = e 2X −1 [log r] 1 = 0 · 1 + 1 · 2 + 2 · 22 + ... + (e − 1)2e−1 . Let f (x) = 1 + x + x2 + ... + xe−1 xe − 1 = x−1 Then f 0 (x) = 1 + 2x + ... + (e − 1)xe−2 exe−1 xe − 1 = − x − 1 (x − 1)2 Hence N (2e − 1) = 2f 0 (2) = 2e2e−1 − 2(2e − 1) = (e − 2)2e + 2. In particular N (29 − 1) = 7 · 28 + 2 ie N (511) = 1538 After this we are adding 8 for each number. Since 1538 = 2 mod 8, we get numbers = 2 mod 8, such as 2010. 5. If the number n is chosen at random, what is the probability that 2n ends in 2? 6. If the number n is chosen at random, what is the probability that 2n starts with 1? 7. Let us say that a number is almost-prime if it is not divisible by 2,3,5 or 7. How many almost-prime numbers are there less than 1,000? Answer: Let S(r) be the natural numbers ≤ 1000 that are divisible by r: S(r) = {1 ≤ n ≤ 1000 : r | n}. Then #S(r) = [1000/r]. We have to determine the number of elements in X = [1, 1000] \ (S(2) ∪ S(3) ∪ S(5) ∪ S(7)). By the Principle of Inclusion-Exclusion, #(S(2) ∪ S(3) ∪ S(5) ∪ S(7)) =#S(2) + #S(3) + #S(5) + #S(7) − #(S(2) ∩ S(3)) − #(S(2) ∩ S(5)) − #(S( + #(S(3) ∩ S(5)) + #(S(3) ∩ S(7)) + #(S( − #(S(2) ∩ S(3) ∩ S(5)) + #(S(2) ∩ S(5) ∩ − #(S(2) ∩ S(3) ∩ S(7)) − #(S(3) ∩ S(5) ∩ + #(S(2) ∩ S(3) ∩ S(5) ∩ S(7) 8. 8 people are sitting round a circular table. In how many ways can they change places so that each person has a different neighbour to the right? Answer: Let us solve the problem with a set X of n people around the table. Let the number of solutions be f (n). For simplicity let us number the people 0, 1, . . . , n−1 mod n. Consider a permutation π of the set X. Suppose in fact just r people still have the same person on their right, Then we can define a permutation σ of the n − r remaining people X \ S by identifying i with i + 1 if π(i + 1) ≡ π(i) + 1. Thus suppose the interval [j, k] ⊂ X, ie π(i + 1) ≡ π(i) + 1. for i = j, j + 1, . . . , j + k, but π(j − 1) 6≡ π(j) − 1, π(k + 1) 6≡ π(k) + 1; and suppose π(`) = j. Then we set σ(`) = k. 9. If a set of circles is placed in the plane so that no circle in the set lies inside another one, does it follow that the set is enumerable? Answer: 10. Can you find 3integers x, y, z, not all zero, such that x3 + 2y 3 + 4z 3 = 0? Answer: 11. What point P in a triangle ABC minimises AP 2 + BP 2 + CP 2 ? Answer: 12. Show that in a group of 6 people there are either 3 people who know each other (“mututal acquaintances”) or 3 people who don’t know each other (“Mutual strangers”) Answer: 13. Show that the complex numbers x, y, z form an equilateral triangle if and only if x2 + y 2 + z 2 = xy + yz + zx. Answer: 14. Show that in any graph with at least 2 vertices there must be 2 vertices with the same degree. (The degree of a vertex is the number of edges with an end-point at that vertex.) Answer: 15. Show that for any k > 2 one can find k integers 0 < a1 < a2 < · · · < ak such that 1 1 1 + + ··· = 1. a1 a2 ak Answer: We have 1 1 1 + + = 1. 2 3 6 Suppose 1 1 1 + + ··· = 1. a1 a2 ak Then 1 1 = k ak 1 1 1 + + 2 3 6 = 1 1 1 += += , 2ak 3ak 6ak giving a sum of the same kind with 2 additional terms. The sum 1 1 + =1 2 2 gives successive sums with 4, 6, 8, . . . terms, while 1 1 1 + + = 1. 2 3 6 gives successive sums with 5, 7, 9, . . . terms. Thus we have solutions for all k ≥ 3. Challenge Problem Do there exist primes p, q such that p | q(q − 1) + 1 and q | p(p − 1) + 1? Answer: