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Honors question 4: Continued fractions. Recall that the rational numbers, denoted Q, are precisely those numbers that can be expressed as ratios of integers, pq . Every rational number pq ∈ Q has a continued fraction expansion: 1 p = a1 + q a2 + 1 a3 + a4 + 1 1 a5 +... 1 an where a1 , a2 , ..., an ∈ Z with a2 , ..., an positive. For example, consider the rational number continued fraction expansion given by: 1 2+ 1 + 2+1 1 19 7 . This has 2 since 2+ 1 1+ 1 2+ 12 =2+ 1 1+ 1 =2+ 5 2 1 1+ =2+ 2 5 1 7 5 (a.) Find the continued fraction expansion for the rational numbers equations would be helpful to get you started on the first one: =2+ 5 19 = 7 7 81 237 1376 35 , 29 , 231 . Perhaps the following 81 = 2 · (35) + 11 35 = 3 · (11) + 2 11 = 5 · (2) + 1 2 = 2 · (1) This notion of a continued fraction expansion for a rational number also makes sense for any real number, but now the sequence is no longer finite. More precisely, given any real number x ∈ R, there is an infinite sequence {an }∞ n=1 , where each an ∈ Z with an > 0 for n ≥ 2, so that x is the limit of the sequence of partial quotients x = lim qn n→∞ which are defined by q1 = a 1 1 a2 1 q3 = a 1 + a2 + a13 q2 = a 1 + q4 = a 1 + 1 a2 + 1 a3 + a1 4 q5 = a 1 + 1 a2 + 1 a3 + 1 a4 + 1 a5 and so on, with the nth term given by qn = a 1 + 1 a2 + 1 a3 + 1 a4 + 1 1 a5 +... 1 an It is not obvious that such a sequence would converge, but indeed, for any sequence {a n }∞ n=1 with an ∈ Z for every n and an > 0 for n ≥ 2, this does indeed converge. For those that are interested in trying to see why this converges, let me give you a hint: Prove that the sequence is a Cauchy sequence—see the appendix in your book for this definition. As we know, the rational numbers sit inside the real numbers Q ⊂ R. There is another set of numbers Q which lies strictly between the rational and real numbers called the algebraic numbers, Q ⊂ Q ⊂ R defined to be the set of numbers x which satisfy a polynomial with integer coefficients: x∈Q if and only if b0 + b1 x + b2 x2 + ... + bn xn = 0 for some b0 , ..., bn ∈ Z (b.) Verify that Q ⊂ Q. That is, show √ that every rational number satisfies a polynomial equation with integer coefficients. Also check that n ∈ Q for every n ∈ Z. The algebraic numbers can be characterized in terms of continued fraction expansions. In particular if the continued fraction expansion of x is repeating, then x is an algebraic number. To say that the sequence is repeating means that it repeats a given finite string of integers over and over. E.g. 1, 3, 5, 2, 1, 3, 5, 2, 1, 3, 5, 2, ..... (c.) Verify this fact for sequences that repeat strings of length 2, 3, and 4. That is, for sequences of the form a, b, a, b, a, b, a, b, a, b, ... and a, b, c, a, b, c, a, b, c, a, b, c, ... and a, b, c, d, a, b, c, d, a, b, c, d, a, b, c, d, ... 2