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To find an order of an element, y in X, we just have to find a power of the modulo where it will repeat itself. So
 
To find an order of an element, y in X, we just have to find a power of the modulo where it will repeat itself. So
  
<math> 7^0 = 1 , the remainder when 15|1 = 1
+
<math> 7^0 = 1 </math>, the remainder when 15|1 = 1
  
7^1 = 7 , remainder = 7
+
<math>7^1 = 7 </math>, remainder = 7
  
7^2 = 49 , remainder of 15|49 = 4
+
<math>7^2 = 49 </math>, remainder of 15|49 = 4
  
7^3 = 343 , remainder of 15|343 = 13
+
<math>7^3 = 343 </math>, remainder of 15|343 = 13
  
7^4 = 2401, remainder of 15|2401 = 1
+
<math>7^4 = 2401 </math>, remainder of 15|2401 = 1
  
The remainder of 7^4 is the same as 7^0, and so we can end here since it the remainders will repeat itself </math>
+
The remainder of <math> 7^4 </math> is the same as <math> 7^0 </math>, and so we can end here since it the remainders will repeat itself  
 
So, the order of |7| = 4 since it has to go through 4 numbers before it repeats itself again.
 
So, the order of |7| = 4 since it has to go through 4 numbers before it repeats itself again.

Revision as of 19:54, 16 September 2008

The problem says show that U(20) does not equal <k> for any k in U(20). [Hence U(20) is not cyclic.] I was trying to understand Example 1 from the Chapter 3 in the text book. where it discusses U(15). I am completely confused about what it is talking about:

U(15) = {1, 2, 4, 7, 8, 11, 13, 14 } Then it goes on to say to find the order of element 7, so |7| = 4 $ 7^1 = 7space 7^2 =4 space 7^3 = 13 space 7^4 = 1 $


Let U(a) = X where X is a group with several elements. Let Z = b + n*a, so all elements in X will satisfy gcd(a,b) = 1.

So for U(15) we'll get {1, 2, 4, 7, 8, 11, 13, 14}

To find an order of an element, y in X, we just have to find a power of the modulo where it will repeat itself. So

$ 7^0 = 1 $, the remainder when 15|1 = 1

$ 7^1 = 7 $, remainder = 7

$ 7^2 = 49 $, remainder of 15|49 = 4

$ 7^3 = 343 $, remainder of 15|343 = 13

$ 7^4 = 2401 $, remainder of 15|2401 = 1

The remainder of $ 7^4 $ is the same as $ 7^0 $, and so we can end here since it the remainders will repeat itself So, the order of |7| = 4 since it has to go through 4 numbers before it repeats itself again.

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