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The '''base conversion divisibility test''' is a process that can be used to determine whether or not a certain (positive) [[natural number]] ''a'' can be divided evenly into a larger natural number ''b''. It is the general case for the well-known test for [[9 (number)|divisibility by nine]]. For other [[divisor]]s, applying this test is generally harder than figuring it out by normal division. | |||
==Example== | |||
Is 312 divisible by 13? | |||
*a=13 | |||
*b=312 | |||
*x=a+1=14 | |||
*y=b (base-14)=184 (312 in base x) | |||
*z=1+8+4=13 | |||
*z/a=13/13=1, a natural number | |||
312 is divisible by 13. | |||
==Example== | |||
this can be solved by another method. | |||
a=3 | |||
b=1 | |||
c=2 | |||
now, | |||
10a=30 | |||
b=1 | |||
4c=8; | |||
thus 10a+b+4c=30+1+8=39,which is divisible by 13. | |||
For 2-digit numbers:- | |||
if a+4b is divisible by 13 then 10a+b is divisible by 13. | |||
==Example== | |||
is 91 divisible by 13? | |||
a=9 | |||
b=1 | |||
therefore a+4b=9+4*1=13,which is divisible by 13 | |||
thus 91(13*7=91) is divisible by 13. | |||
==Dividing by nine== | |||
The trick for determining if a number is divisible by nine is well-known: If the sum of the digits of a number is divisible by nine, then the number itself is as well. This is a special case of the general rule, made easy because no base conversion is necessary since 9 + 1 = 10, and we already use base 10. | |||
Example: | |||
Is 2,340 divisible by 9? | |||
*a=9 | |||
*b=2,340 | |||
*x=a+1=10 | |||
*y=b (base-10)=2,340 | |||
*z=2+3+4+0=9 | |||
*z/a=9/9=1, a natural number | |||
2,340 is divisible by 9. | |||
==Proof== | |||
Any number can be expressed as | |||
<math>number_{(base)} = \sum_{i=0}^n {digits_i \times base^i}</math> | |||
We know that under [[Modulo Arithmetic]], <math>base \equiv_{(base - 1)} 1</math> | |||
Thus <math>number \equiv_{(base-1)} \sum_{i=0}^n{digits_i} \times 1</math> | |||
[[Category:Arithmetic]] |
Latest revision as of 13:46, 20 April 2013
The base conversion divisibility test is a process that can be used to determine whether or not a certain (positive) natural number a can be divided evenly into a larger natural number b. It is the general case for the well-known test for divisibility by nine. For other divisors, applying this test is generally harder than figuring it out by normal division.
Example
Is 312 divisible by 13?
- a=13
- b=312
- x=a+1=14
- y=b (base-14)=184 (312 in base x)
- z=1+8+4=13
- z/a=13/13=1, a natural number
312 is divisible by 13.
Example
this can be solved by another method. a=3 b=1 c=2 now, 10a=30 b=1 4c=8; thus 10a+b+4c=30+1+8=39,which is divisible by 13. For 2-digit numbers:- if a+4b is divisible by 13 then 10a+b is divisible by 13.
Example
is 91 divisible by 13? a=9 b=1 therefore a+4b=9+4*1=13,which is divisible by 13 thus 91(13*7=91) is divisible by 13.
Dividing by nine
The trick for determining if a number is divisible by nine is well-known: If the sum of the digits of a number is divisible by nine, then the number itself is as well. This is a special case of the general rule, made easy because no base conversion is necessary since 9 + 1 = 10, and we already use base 10.
Example: Is 2,340 divisible by 9?
- a=9
- b=2,340
- x=a+1=10
- y=b (base-10)=2,340
- z=2+3+4+0=9
- z/a=9/9=1, a natural number
2,340 is divisible by 9.
Proof
Any number can be expressed as
We know that under Modulo Arithmetic,