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I am doing a problem in which I have to find the last two digits before the decimal point for the number
[4 + sqrt(11)]n.

For example, when n = 4, [4 + sqrt(11)]4 = 2865.78190... the answer is 65. Where n can vary from 2 <= n <= 109.

My solution - I have tried to build a square root function which calculate the sqrt of 11 which a precision equal to value of n input by the user.

I have used BigDecimal in Java to avoid overflow problems.

public class MathGenius {

    public static void main(String[] args) {

        Scanner reader = new Scanner(System.in);
        long a = 0;
        try {
            a = reader.nextInt();
        } catch (Exception e) {
            System.out.println("Please enter a integer value");
            System.exit(0);
        }

        // Setting precision for square root 0f 11. str contain string like 0.00001
        StringBuffer str = new StringBuffer("0.");
        for (long i = 1; i <= a; i++)
            str.append('0');
        str.append('1');

        // Calculating square root of 11 having precision equal to number enter
        // by the user.
        BigDecimal num = new BigDecimal("11"), precision = new BigDecimal(
                str.toString()), guess = num.divide(new BigDecimal("2")), change = num
                .divide(new BigDecimal("4"));
        BigDecimal TWO = new BigDecimal("2.0");
        BigDecimal MinusOne = new BigDecimal("-1"), temp = guess
                .multiply(guess);
        while ((((temp).subtract(num)).compareTo(precision) > 0)
                || num.subtract(temp).compareTo(precision) > 0) {

            guess = guess.add(((temp).compareTo(num) > 0) ? change
                    .multiply(MinusOne) : change);

            change = change.divide(TWO);
            temp = guess.multiply(guess);
        }

        // Calculating the (4+sqrt(11))^n
        BigDecimal deci = BigDecimal.ONE;
        BigDecimal num1 = guess.add(new BigDecimal("4.0"));
        for (int i = 1; i <= a; i++)
             deci = deci.multiply(num1);

        // Calculating two digits before the decimal point
        StringBuffer str1 = new StringBuffer(deci.toPlainString());
        int index = 0;
        while (str1.charAt(index) != '.')
            index++;
        // Printing output

        System.out.print(str1.charAt(index - 2));
        System.out.println(str1.charAt(index - 1));
    }
}

This solution works up to n = 200, but then it begins to slow down. It stops working for n = 1000.

What is a good method to deal with problem?

2 -- 53
3 -- 91
4    65
5    67
6    13
7    71
8    05
9    87
10   73
11   51
12   45
13   07
14   33
15   31
16   85
17   27
18   93
19   11
20   25
21   47
22   53
23   91
24   65
25   67
share|improve this question
4  
I would look for a pattern in those first 200... then maybe do an inductive proof to say that there really is a pattern; then use that instead of calculating this. –  d'alar'cop Feb 23 '14 at 5:27
1  
@d'alar'cop - can u explain which pattern ??? –  T.J. Feb 23 '14 at 5:29
    
Can you post the first 20 or so of the results? - I mean just those 2 digits you are looking for –  d'alar'cop Feb 23 '14 at 5:30
4  
ALSO, there is a pretty damn obvious pattern in there... from n=22 it's starting from n=2 again... check if that's consistent. Then just keep those nums in an array... then base your result on the provided n with appropriate %ing. –  d'alar'cop Feb 23 '14 at 5:47
2  
there is a pattern repeating at n=22 @d'alar'cop –  T.J. Feb 23 '14 at 5:49

2 Answers 2

up vote 1 down vote accepted

At n=22 the results seem to repeat from the position of n=2. So keep those 20 values in an array in the same order as in your list e.g. nums[20].

Then when the user provides an n:

return nums[(n-2)%20]

There is now a proof of this pattern repeating here.

Alternatively, if you insist on computing at length; since you calculating the power by looping multiplication (and not BigDecimal pow(n)) you could trim the number you are working with at the front to the last 2 digits and the fractional part.

share|improve this answer
    
are you sure it repeats after 22 ? ideone.com/TA0Re6 –  Jigar Joshi Feb 23 '14 at 6:00
    
@JigarJoshi No. I'd want to do some more tests and maybe a proof. But I did say "seems" and I also showed an alternative solution just in case. However, in the question comments, OP says that there is indeed a pattern - I'm not sure how he verified this. –  d'alar'cop Feb 23 '14 at 6:03
2  
Nathaniel Johnston posted a proof at MO: mathoverflow.net/questions/158420 –  Noah Snyder Feb 23 '14 at 18:21
    
@NoahSnyder Thank you, sir. Very nicely done by Nathaniel. It's nice to see the proof! –  d'alar'cop Feb 24 '14 at 2:12

Here is a much simpler solution for you...

Use the rational representation of 4+sqrt(11):

BigInteger hundred     = new BigInteger("100");
BigInteger numerator   = new BigInteger("5017987099799880733320738241");
BigInteger denominator = new BigInteger("685833597263928519195691392");
BigInteger result = numerator.pow(n).divide(denominator.pow(n)).mod(hundred);

UPDATE:

As you've mentioned in the comments below, this procedure is prone to precision-loss, and will eventually yield an incorrect result. I found this question to be rather interesting on the mathematical aspect, and so I published a question on MO (http://mathoverflow.net/q/158420/27456).

You can read the answer at http://mathoverflow.net/a/158422/27456.

share|improve this answer
    
4+sqrt(11) is irrational .. after some time round off error will be significant –  T.J. Feb 23 '14 at 6:15
    
@T.J, but that is true regardless of anything you do on any Turing machine (i.e. any modern computer)!!!!! Your calculation will eventually take place with a rational number, whether you use the numerator/denominator above, or any other function which calculates the square root of 11. –  barak manos Feb 23 '14 at 6:19
    
but i need to calculate the exact value ..Question was to actually look for pattern in it ... ronding error will make answers differ from one another. Twist is not to calculate but to find pattern. –  T.J. Feb 23 '14 at 6:26
    
@T.J: For double val = 4+sqrt(11), the numerator/denominator above are 100% accurate, with no loss of precision. Of course, the precision-loss itself occurs when you use sqrt, but you cannot avoid this (unless you implement a BigRational class, which calculates the square root to a more accurate level then provided by the double type). My suggestion is merely a simpler and more accurate method for tackling the problem described at your question. If you're looking for the actual pattern, then that's a different issue. –  barak manos Feb 23 '14 at 6:30

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