Solve (3x \equiv 5 \pmod11).
Assume (\sqrt2 = p/q) in lowest terms ((p,q\in\mathbbZ), (\gcd(p,q)=1)). Squaring: (2q^2 = p^2 \Rightarrow p^2) even (\Rightarrow p) even. Write (p=2k). Then (2q^2 = 4k^2 \Rightarrow q^2 = 2k^2 \Rightarrow q) even. Contradiction since (\gcd(p,q)\ge 2). Hence (\sqrt2) irrational. Chapter 2 – Natural Numbers and Induction Exercise 2.3 Prove by induction: (1 + 2 + \dots + n = \fracn(n+1)2) for all (n\in\mathbbN). Concise Introduction To Pure Mathematics Solutions Manual
[ \left|\frac3n+12n+5 - \frac32\right| = \left|\frac2(3n+1) - 3(2n+5)2(2n+5)\right| = \left|\frac-132(2n+5)\right| = \frac132(2n+5) < \frac134n ] Given (\varepsilon>0), choose (N > \frac134\varepsilon). Then for (n\ge N), (\frac134n<\varepsilon), so the difference (<\varepsilon). QED. Chapter 10 – Continuity and Limits Exercise 10.4 Show (f(x)=x^2) is continuous at (x=2). Solve (3x \equiv 5 \pmod11)
Case 1: first digit odd (4 choices: 1,3,5,7,9? Actually 5 odds, but careful: first digit ≠0, so even allowed but handled separately). Better systematic: Choose positions for the two even digits: (\binom42=6) ways. Write (p=2k)
Find remainder when (x^100) is divided by (x^2-1).
(x^2 < 1 \Rightarrow x^2 -1 < 0 \Rightarrow (x-1)(x+1) < 0). Product negative iff one factor positive, the other negative. Case 1: (x-1<0) and (x+1>0) → (x<1) and (x>-1) → (-1<x<1). Case 2: (x-1>0) and (x+1<0) impossible (would require (x>1) and (x<-1)). Thus (-1<x<1).