8

I wanted to know how I can generate pi to the nth digit. I have a couple of basic ideas.

  1. Use Math.PI and increase the precision (if that's possible)
  2. Use Euler's formula to generate pi but even here, I would need to increase the precision (I think) Euler's formula for PI
  3. There is also Srinivasa Ramanujan's formula for generating PI which is known for it's rapid convergence. This formula seems difficult to implement. I believe, I would have to also increase deicmal precision here.
    enter image description here

So in short, either way, I would need to increase the precision of BigDecimal depending on what the nth digit is. How would I go about increasing the precision of BigDecimal to nth digit? Also, if there is a better and faster of doing this, can you please point me in the correct direction.

EDIT: I just want to generate PI. I don't want to use for calculations. and this is a question about how I can use BigDecimal to implement my ideas of generating PI.

  • Do you actually need to generate Pi or do you need it for calculations? – Goran Jovic Dec 3 '11 at 19:24
  • Is this a question about the maths behind computing pi, or about how to use BigDecimal? – Oliver Charlesworth Dec 3 '11 at 19:24
  • I'm just using BigDecimal to implement the PI formulae and I don't need PI to calculate, I just want to generate it. – Jeel Shah Dec 3 '11 at 19:26
6
  • Math.PI is of type double. That means about 15 decimal digits of precision, and that is all the data you have; nothing will magically make additional digits of PI appear.
  • BigDecimal has arbitrary precision. setScale() allows you to create BigDecimal objects with as much precision as you want and most of the arithmetic methods will automatically increase precision as required, but of course the more precision, the slower all calculations will be.
  • The most difficult part of implementing Ramanujan's formula will ironically be the sqrt(2) in the constant factor, because there is not built-in sqrt() for BigDecimal, so you'll have to write your own.
  • But for the square root, the good old Heron method converges fast enough even with a million (or a billion) digits of precision. – Daniel Fischer Dec 3 '11 at 19:41
  • for the sqrt(2) part, can I not just use the pre-defined value? 1.41421356, or will that change the calculation somehow? – Jeel Shah Dec 3 '11 at 19:46
  • @user681159: well, as soon as you want your value of PI to be more precise that that "pre-defined value", you'll need more digits of sqrt(2). – Michael Borgwardt Dec 3 '11 at 19:47
  • 2
    @user681159: Isn't it pretty obvious that if you want to calculate a very precise result based in a specific constant factor, you can't do that with an imprecise approximation of that factor? – Michael Borgwardt Dec 3 '11 at 19:50
  • sorry, I missed that. Cut me some slack. – Jeel Shah Dec 3 '11 at 19:56
3

You need to use MathContext to increase the precision of the BigDecimal

e.g.

MathContext mc = new MathContext(1000);
BigDecimal TWO = new BigDecimal(2, mc);

It's important that ALL the BigDecimals you use in your calculations use that MathContext. Heron's method should give you 1000 digits precision with only 10 iterations and a million digits with 20 iterations so it's certainly good enough. Also, create all the constant BigDecimals like e.g. 26390 only once at the start of your program.

  • What do you mean by Heron's method? – Jeel Shah Dec 4 '11 at 1:33
  • @user681159 Heron's method coincides with the Newton-Raphson method for the case of square roots, in case you are familiar with the latter. Otherwise: it's finding better approximations to sqrt(a) via x_(n+1) = 1/2*(x_n + a/x_n). It converges for all a > 0 and any starting value x_0 > 0. If you start with a fairly good approximation, in each step the number of correct digits doubles (approximately). – Daniel Fischer Dec 4 '11 at 4:10
0

You can use this code

import java.math.BigDecimal;
import java.math.RoundingMode;

public final class Pi {

private static final BigDecimal TWO = new BigDecimal("2");
private static final BigDecimal FOUR = new BigDecimal("4");
private static final BigDecimal FIVE = new BigDecimal("5");
private static final BigDecimal TWO_THIRTY_NINE = new BigDecimal("239");

private Pi() {}

public static BigDecimal pi(int numDigits) {

  int calcDigits = numDigits + 10;

  return FOUR.multiply((FOUR.multiply(arccot(FIVE, calcDigits)))
    .subtract(arccot(TWO_THIRTY_NINE, calcDigits)))
    .setScale(numDigits, RoundingMode.DOWN);
}

 private static BigDecimal arccot(BigDecimal x, int numDigits) {

BigDecimal unity = BigDecimal.ONE.setScale(numDigits,
  RoundingMode.DOWN);
BigDecimal sum = unity.divide(x, RoundingMode.DOWN);
BigDecimal xpower = new BigDecimal(sum.toString());
BigDecimal term = null;

boolean add = false;

for (BigDecimal n = new BigDecimal("3"); term == null ||
  term.compareTo(BigDecimal.ZERO) != 0; n = n.add(TWO)) {

  xpower = xpower.divide(x.pow(2), RoundingMode.DOWN);
  term = xpower.divide(n, RoundingMode.DOWN);
  sum = add ? sum.add(term) : sum.subtract(term);
  add = ! add;
}
return sum;
}
}

resource

  • There is a problem with this code it leads to an infinite loop under certain conditions ;-( – Werner Keil Nov 3 '16 at 18:18

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