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I read this great question about showing and doing simple arithmetic on them, but I am wondering given this (or simply starting from scratch), how to show and then further similarly do arithmetic on them when given a different base?

For example,

(1/3)_2=0.01 means the fraction 1/3 in binary form is repeating the binary digits 01.

Thank you.

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By the way, it would be nice if we could enter repeating decimals directly through the keyboard through some keystroke combinations. That presumes of course that Mma would have an underlying knowledge of such decimals. –  David Carraher Dec 3 '11 at 1:35
    
yes, that is the ideal. :) –  Qiang Li Dec 3 '11 at 1:51

3 Answers 3

up vote 4 down vote accepted

Here's an attempt. Mr.Wizard did much of the heavy lifting, especially in the base-preserving arithmetic.

rd[n_] := rd[n, 10]
rd[rd[n_, _], b_] := rd[n, b]

Format[rd[n_Integer | n_Real, base_]] := BaseForm[n, base]

Format[rd[q_Rational, base_]] :=
  Subscript[Row @ Flatten[{
     IntegerString[IntegerPart@q, base], ".",
     RealDigits[FractionalPart@q, base] /.
      {{nr___, r_List:{}}, pt_} :> {0~Table~{-pt}, nr, OverBar /@ r}
   }], base /. 10 -> ""]

Base-preserving arithmetic can be implemented using this:

Scan[
  (#[rd[q1_, b1_], rd[q2_, b2_] | tail___] ^:=
     rd[ #[q1, q2, tail], If[b1 === b2, b1, 10] ]) &,
  {Plus, Times, Power}
]

Checking to see that conversions to repeating decimals in several bases work. Also checking routines for adding, multiplying, and dividing:

Grid[{{"n", "value", "decimal", "rd[n,10]", "rd[n,2]", "rd[n,3]",  "rd[n,7]"}, 
 {"a", a = 14/3, N[a], rd[a, 10], rd[a, 2], rd[a, 3],  rd[a, 7]}, 
 {"b", b = 2/5, N[b], rd[b, 10], rd[b, 2], rd[b, 3], rd[b, 7]}, 
 {"c", c = 1/2, N[c], rd[c, 10], rd[c, 2], rd[c, 3], rd[c, 7]}, 
 {"a + b", a + b, N[a + b], rd[a, 10] + rd[b, 10], 
    rd[a, 2] + rd[b, 2], rd[a, 3] + rd[b, 3], rd[a, 7] + rd[b, 7]}, 
 {"a + b + c", a + b + c, N[a + b + c], 
   rd[a, 10] + rd[b, 10] + rd[c, 10], rd[a, 2] + rd[b, 2] + rd[c, 2], 
   rd[a, 3] + rd[b, 3] + rd[c, 3], 
   rd[a, 7] + rd[b, 7] + rd[c, 7]}, 
 {"a \[Times] b ", a*b, N[a*b], 
    rd[a, 10]*rd[b, 10], rd[a, 2]*rd[b, 2], rd[a, 3]*rd[b, 3], 
    rd[a, 7]*rd[b, 7]}, {"a \[Times] b \[Times] c ", a*b*c, N[a*b*c], 
    rd[a, 10]*rd[b, 10]*rd[c, 10], rd[a, 2]*rd[b, 2]*rd[c, 2], 
    rd[a, 3]*rd[b, 3]*rd[c, 3], rd[a, 7]*rd[b, 7]*rd[c, 7]}, 
 {"a / b", 
    a/b, N[a/b], rd[a, 10]/rd[b, 10], rd[a, 2]/rd[b, 2], 
    rd[a, 3]/rd[b, 3], rd[a, 7]/rd[b, 7]}}, Dividers -> All]

summary table


Edit

The latest refinements (credit, once again, to Mr.Wizard) support nesting:

ClearAll[f, x, y]
f := (x/(x + 3 + 2 y) + y)/7 x; f
f // FullForm
x = 14/3; y = 1/3; f
BaseForm[N[f], 10]
x = rd[14/3, 10]; y = rd[1/3, 10]; f
x = rd[14/3, 2]; y = rd[1/3, 2]; f
x = rd[14/3, 5]; y = rd[1/3, 5]; f

nesting

share|improve this answer
    
+1, yes, that is exactly what I have in mind. :) –  Qiang Li Dec 3 '11 at 0:35
    
I'll play around and see what I can come up with. –  David Carraher Dec 3 '11 at 0:39
    
@Mr. Glad to have your help. You may be correct about the final line. When I dug up the old code, the final 3 lines were all hidden. Let me see what you came up with. At the present moment, calculation in bases other than 10 is not implemented. –  David Carraher Dec 3 '11 at 8:35
1  
I removed the line rd /: (h : Plus | Times) . . . as that appeared to be redundant given the commutative property of Plus and Times. Does the code as now shown pass your battery of tests? –  Mr.Wizard Dec 3 '11 at 9:42
1  
@Mr.Wizard All the routines work fine. Thanks so much for your help! –  David Carraher Dec 3 '11 at 22:21

Simple: BaseForm[1./12, 3] will show you 1/12 (the decimal point after the 1 is to ensure approximation) in base 3 as a repeating decimal.

Extra: Converting base x to base ten is even simpler x^^<NUMBER>

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+1 for the decimal point, which I hadn't seen employed in BaseForm before. There is still something to do: your approach doesn't unambiguously identify the repeating part, but it is a great thing to know, nonetheless. –  David Carraher Dec 3 '11 at 0:36

'RealDigits' is able to handle all kinds of bases, so for instance

RealDigits[1/3, 2]

{{{1, 0}}, -1}

Refer to the documentation about the precise output format you may get. It can be rather complex.

share|improve this answer
    
Thank you for pointing that out. However, what I asked is how to do the exactly same thing as the original link did, showing the repeating decimal and then do some arithmetic such as addition/subtraction etc. –  Qiang Li Dec 2 '11 at 22:04
    
@Qiang The part of doing "some arithmetic" is a bit vague. Could you please elaborate? –  Sjoerd C. de Vries Dec 2 '11 at 22:10
    
For example, after showing the repeating decimal of (1/3)_2, I want it can deal with the situation (1/3)_2+(5/3)_2=10_2 –  Qiang Li Dec 2 '11 at 22:18
    
@QiangLi Couldn't you just do the arithmetic as always and pipe the result through RealDigits? –  Sjoerd C. de Vries Dec 2 '11 at 22:54

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