Line 2: Line 2:
  
 
[[Week 2]]-Jan 22 (In[tro]duction, 0): Ch 0: 25, 24, 7, 14, 19, 21
 
[[Week 2]]-Jan 22 (In[tro]duction, 0): Ch 0: 25, 24, 7, 14, 19, 21
Chapter 0: 24, 25, 7, 14, 19, 21
 
Due Thursday, January 22
 
  
-- It's kind of funny that it starts at chapter 0.  Very CS of Joe!  [[User:eraymond|eraymond]] 13:56, 19 January 2009 (UTC)
+
[[Week 3]]-Jan 29 (Groups, 1+5): Ch 1: 6, 13. Ch 5: 6,8, 19, 43
 
+
 
+
[[Problem 24]]
+
*If p is prime and p divides a_1a_2...a_n, prove that p divides a_i for some i
+
*In class we proved this for the case where <math>p|ab</math>. I was unable to extend that proof for <math>n</math> factors of <math>a</math>. Anyone figure this out?
+
**I updated the page with a [[Problem 24|link]] to the solution. -Nick
+
 
+
Problem 25
+
*Use the Generalized Euclid's Lemma to establish the uniqueness portion of the Fundamental Theorem of Arithmetic
+
 
+
Problem 7
+
*Show that if a and b are positive integers, then ab = lcm(a, b) * gcd (a,b)
+
*I completed this problem by writing a and b as prime factorizations, with the gcd and lcm having the min and max of their exponents respectively. --[[User:Podarcze|Podarcze]] 15:15, 20 January 2009 (UTC)
+
 
+
Problem 14
+
*Show that 5n + 3  and 7n + 4 are relatively prime for all n
+
*You can use Euclid's Algorithm to show that <math>gcd(5n+3,7n+4)=1</math>. Start with <math>(7n+4)=1*(5n+3)+(2n+1)</math> and iterate until the remainder is 0.
+
 
+
Problem 19
+
*Prove that there are infinitely many primes. (hint: use ex. 18)
+
 
+
[[Problem 21]]
+
*For every positive integer n, prove that a set with exactly n elements has exactly 2^n subsets (counting the empty set and the entire set)
+
 
+
 
+
--[[User:Aifrank|Aifrank]] 13:56, 18 January 2009 (UTC)
+

Revision as of 13:56, 22 January 2009


Week 2-Jan 22 (In[tro]duction, 0): Ch 0: 25, 24, 7, 14, 19, 21

Week 3-Jan 29 (Groups, 1+5): Ch 1: 6, 13. Ch 5: 6,8, 19, 43

Alumni Liaison

Basic linear algebra uncovers and clarifies very important geometry and algebra.

Dr. Paul Garrett