# Finding the last two digits before the decimal point for the number (4+sqrt(11))^n

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) {

long a = 0;
try {
} catch (Exception e) {
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;
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
``````
• 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
• @d'alar'cop - can u explain which pattern ??? – T.J. Feb 23 '14 at 5:29
• 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
• there is a pattern repeating at n=22 @d'alar'cop – T.J. Feb 23 '14 at 5:49

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.

• 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
• 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 (https://mathoverflow.net/q/158420/27456).

• @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