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Maybe a stupid question but should we prove if a=b then (a+c)=(b+c) if we want to use this property? Can't find where it is given in the book.
 
Maybe a stupid question but should we prove if a=b then (a+c)=(b+c) if we want to use this property? Can't find where it is given in the book.
  
Dr. Alekseenko (corrected 01/26/2010 7:20pm): Indeed, the book does not seem to have this statement in it proved.  
+
Dr. Alekseenko ('''corrected 01/26/2010 7:20pm'''): Indeed, the book does not seem to have this statement in it proved.  
  
 
First of all, let us establish that <math> -(b+c)=(-b)+(-c)</math>. Indeed,  
 
First of all, let us establish that <math> -(b+c)=(-b)+(-c)</math>. Indeed,  
 
consider:
 
consider:
<math> -(b+c) = \mathrm{axiom\ of\ zero\ ele.}\ } -(b+c)+ 0 + 0 = </math>
+
 
 +
<math> -(b+c) = </math>
 +
 
 +
Use the axiom of zero element
 +
 
 +
<math> -(b+c)+ 0 + 0 = </math>
 +
 
 
Use the axiom of additive inverse:
 
Use the axiom of additive inverse:
 +
 
<math> = -(b+c) + b + (-b) + c + (-c)  = </math>
 
<math> = -(b+c) + b + (-b) + c + (-c)  = </math>
 +
 
Use commutative law on terms #3 and #4:
 
Use commutative law on terms #3 and #4:
 +
 
<math> = -(b+c) + b + c+ (-b) + (-c)  = </math>
 
<math> = -(b+c) + b + c+ (-b) + (-c)  = </math>
 +
 
Use associative law:
 
Use associative law:
 +
 
<math> = -(b+c) + (b + c)+ (-b) + (-c)  = </math>
 
<math> = -(b+c) + (b + c)+ (-b) + (-c)  = </math>
 +
 
Finally, use axiom of inverse (A4) on terms #1 and #2:
 
Finally, use axiom of inverse (A4) on terms #1 and #2:
 +
 
<math> =  0 + (-b) + (-c)  = </math>
 
<math> =  0 + (-b) + (-c)  = </math>
 +
 
and the axiom of zero:
 
and the axiom of zero:
 +
 
<math> =  (-b) + (-c)  = </math>
 
<math> =  (-b) + (-c)  = </math>
 +
 +
  
 
Now consider  
 
Now consider  
 +
 
<math> (a+c) + (-(b+c)) = </math>  
 
<math> (a+c) + (-(b+c)) = </math>  
 +
 
Use the above identity:  
 
Use the above identity:  
 +
 
<math> = a + c + ((-b) + (-c)) =</math>
 
<math> = a + c + ((-b) + (-c)) =</math>
 +
 
and the associative property
 
and the associative property
 +
 
<math> = a + c + (- b) + (-c) =</math>
 
<math> = a + c + (- b) + (-c) =</math>
 +
 
and the commutative property on terms #2 and #3:
 
and the commutative property on terms #2 and #3:
 +
 
<math> = a + (- b) + c + (-c) =</math>
 
<math> = a + (- b) + c + (-c) =</math>
 +
 
Use the additive inverse property (A4):
 
Use the additive inverse property (A4):
 +
 
<math> = a + (- b) + 0 =</math>
 
<math> = a + (- b) + 0 =</math>
 +
 
and the zero element property:
 
and the zero element property:
 +
 
<math> = a + (- b)</math>
 
<math> = a + (- b)</math>
 
  
 
Now if <math> a=b </math> then <math> a + (-b) = b + (- b)=0 </math>
 
Now if <math> a=b </math> then <math> a + (-b) = b + (- b)=0 </math>
 +
Thus, according to our derivation,
  
 +
<math> (a+c) + (-(b+c)) = 0 </math>
  
 +
which together with
  
next associative law, again,
+
<math> (b+c) + (-(b+c)) = 0 </math>
  
<math> a - b + ((-c) + c) =</math>
+
By the Theorem about the uniqueness of the inverse element,
 +
implies that
  
finally use axiom of zero, i.e.,  <math> (-c)+c =0 </math> we obtain
+
<math> a + c = b + c  </math>  
  
<math> a + b + 0 </math>
+
Since we have just established it, you do not need to prove it in your homework.
 +
(but you have to put a reference to this proof).
  
then, again by the zero axiom
+
----
  
<math> a + b </math>
+
--[[User:Rrichmo|Rrichmo]] 16:12, 27 January 2010 (UTC)
  
Since we have just established it, you do not need to prove it in your homework.
+
Is it given that the sum and product of two integers is again an integer?
(but you have to put a reference to this proof).
+
 
 +
Dr. Alekseenko: Yes. It is given. This property is included in the definitions of
 +
addition and multiplication
  
 
----
 
----

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Maybe a stupid question but should we prove if a=b then (a+c)=(b+c) if we want to use this property? Can't find where it is given in the book.

Dr. Alekseenko (corrected 01/26/2010 7:20pm): Indeed, the book does not seem to have this statement in it proved.

First of all, let us establish that $ -(b+c)=(-b)+(-c) $. Indeed, consider:

$ -(b+c) = $

Use the axiom of zero element

$ -(b+c)+ 0 + 0 = $

Use the axiom of additive inverse:

$ = -(b+c) + b + (-b) + c + (-c) = $

Use commutative law on terms #3 and #4:

$ = -(b+c) + b + c+ (-b) + (-c) = $

Use associative law:

$ = -(b+c) + (b + c)+ (-b) + (-c) = $

Finally, use axiom of inverse (A4) on terms #1 and #2:

$ = 0 + (-b) + (-c) = $

and the axiom of zero:

$ = (-b) + (-c) = $


Now consider

$ (a+c) + (-(b+c)) = $

Use the above identity:

$ = a + c + ((-b) + (-c)) = $

and the associative property

$ = a + c + (- b) + (-c) = $

and the commutative property on terms #2 and #3:

$ = a + (- b) + c + (-c) = $

Use the additive inverse property (A4):

$ = a + (- b) + 0 = $

and the zero element property:

$ = a + (- b) $

Now if $ a=b $ then $ a + (-b) = b + (- b)=0 $ Thus, according to our derivation,

$ (a+c) + (-(b+c)) = 0 $

which together with

$ (b+c) + (-(b+c)) = 0 $

By the Theorem about the uniqueness of the inverse element, implies that

$ a + c = b + c $

Since we have just established it, you do not need to prove it in your homework.

(but you have to put a reference to this proof).

--Rrichmo 16:12, 27 January 2010 (UTC)

Is it given that the sum and product of two integers is again an integer?

Dr. Alekseenko: Yes. It is given. This property is included in the definitions of addition and multiplication


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