Better approximation of e with Java

I would like to approximate the value of e to any desired precision. What is the best way to do this? The most I've been able to get is e = 2.7182818284590455. Any examples on a modification of the following code would be appreciated.

``````public static long fact(int x){
long prod = 1;
for(int i = 1; i <= x; i++)
prod = prod * i;
return prod;
}//fact

public static void main(String[] args) {
double e = 1;
for(int i = 1; i < 50; i++)
e = e + 1/(double)(fact(i));
System.out.print("e = " + e);
}//main
``````
• Obviously a double can never contain more digits than its precision. Use a different kind of number. Sep 26, 2009 at 18:14
• Very much what Joren said. The idea of "any desired precision" is fundamentally incompatible with computation in a fixed-width type. Sep 26, 2009 at 18:21

8 Answers

Use a BigDecimal instead of a double.

``````BigDecimal e = BigDecimal.ONE;
BigDecimal fact = BigDecimal.ONE;

for(int i=1;i<100;i++) {
fact = fact.multiply(new BigDecimal(i));

e = e.add(BigDecimal.ONE.divide(fact, new MathContext(10000, RoundingMode.HALF_UP)));
}
``````
• Implementing this gave at runtime: Exception in thread "main" java.lang.ArithmeticException: Non-terminating decimal expansion; no exact representable decimal result. Is something missing? Sep 26, 2009 at 18:59
• Sorry. Division needs a RoundingMode, otherwise BigDecimal throws up when seeing 1/3. Fixed it.
– Zed
Sep 26, 2009 at 19:06
• How do I use this? I do System.out.println(e) after the loop and get 3 Sep 26, 2009 at 19:24
• @flybywire: precision wasn't set, fixed it as well. This time I also tried to ran the code before "publishing" it :).
– Zed
Sep 26, 2009 at 19:46
• How to make a function out of it with a parameter for the number of digits? I tried to use the for loop but it didn't work. Could you help me please? Mar 6, 2016 at 17:03

Your main problem is that `double` has very limited precision. If you want arbitrary precision, you'll have to use `BigDecimal`. The next problem you're going to run into is the limited range of `long` which you're going to exceed very quickly with the factorial - there you can use `BigInteger`.

Have you taken a look at the arbitrary-precision arithmetic in `java.util.BigDecimal`?

``````import java.math.BigDecimal;
import java.math.MathContext;
public class BigExp {
public static void main(String[] args) {
BigDecimal FIFTY =new BigDecimal("50");
BigDecimal e = BigDecimal.ZERO;
BigDecimal f = BigDecimal.ONE;
MathContext context = new MathContext(1000);

for (BigDecimal i=BigDecimal.ONE; i.compareTo(FIFTY)<0; i=i.add(BigDecimal.ONE)) {
f = f.multiply(i, context);
e = e.add(i.divide(f,context),context);

System.out.println("e = " + e);
}
}
}
``````

You will get better results if you count from 49 to 1 instead of 1 to 49 as now.

Went with a variation of Zed and mobrule's code. Works great, thanks! More performance advice anyone?

``````public static BigDecimal factorial(int x){
BigDecimal prod = new BigDecimal("1");
for(int i = x; i > 1; i--)
prod = prod.multiply(new BigDecimal(i));
return prod;
}//fact

public static void main(String[] args) {
MathContext mc = new MathContext(1000);
BigDecimal e = new BigDecimal("1", mc);
for(int i = 1; i < 1000; i++)
e = e.add(BigDecimal.ONE.divide(factorial(i), mc));
System.out.print("e = " + e);
}//main
``````
• Performance advise: stop recalculating the factorial. Use Zed's solution where you do "fact = fact.multiply(new BigDecimal(i))" in the loop, instead of calculating it again. Sep 27, 2009 at 3:49
• As a proof, mobrule's solution runs in 542ms, your version runs in 858ms for 1000 iterations. Sep 27, 2009 at 4:05

More performance advice anyone?

Yes, your calculation of factorial is as inefficient as it gets. It would be better to move that inside the loop where you're summing the terms. The way you're doing things turns a O(N) problem into a O(N^2) problem.

And if this was a real calculation that needed factorials, I'd recommend a table lookup or the incomplete gamma function as the correct way to do it.

The only thing you could have done worse from a performance point of view is a recursive factorial calculation. Then you'd have the additional problem of a huge stack.

To understand why you cannot get "any desired precision" with `double`, read this classic paper:

What Every Computer Scientist Should Know About Floating-Point Arithmetic

Note that that's a quite technical paper. For more basic details of how floating-point numbers work, see this Wikipedia article: Double precision floating-point format

The best approximation of e can be got by using BigDecimal class.

Here is the code for computing the given BigDecimal Value

``````import java.math.BigDecimal;
import java.math.MathContext;

public class ApproximateE {

public static void main(String[] args) {
System.out.println("e~ "+e(new BigDecimal(50)));//the value to approximate

}

static BigDecimal e(BigDecimal n) {
BigDecimal num = new BigDecimal(n + "");
BigDecimal e = BigDecimal.ZERO;
BigDecimal f = BigDecimal.ONE;
MathContext context = new MathContext(25);//digits of precision

/************************************************************************
The formula for approximating e ~
e = 1+(1/1!+1/2!+1/3!...1/i!)
************************************************************************/
for (BigDecimal i = BigDecimal.ONE; i.compareTo(num) < 0; i = i.add(BigDecimal.ONE)) {

f = f.multiply(i, context);
e = e.add(i.divide(f, context), context);

}
return e;
}

}
``````

Returns :

``````e~ 2.718281828459045235360289
``````

The value of f is

``````1
2
6
24
120
720
5040
40320
362880
3628800
39916800
479001600
6227020800
87178291200
1307674368000
20922789888000
355687428096000
6402373705728000
121645100408832000
2432902008176640000
51090942171709440000
1124000727777607680000
25852016738884976640000
620448401733239439360000
1.551121004333098598400000E+25
4.032914611266056355840000E+26
1.088886945041835216076800E+28
3.048883446117138605015040E+29
8.841761993739701954543616E+30
2.652528598121910586363085E+32
8.222838654177922817725564E+33
2.631308369336935301672180E+35
8.683317618811886495518194E+36
2.952327990396041408476186E+38
1.033314796638614492966665E+40
3.719933267899012174679994E+41
1.376375309122634504631598E+43
5.230226174666011117600072E+44
2.039788208119744335864028E+46
8.159152832478977343456112E+47
3.345252661316380710817006E+49
1.405006117752879898543143E+51
6.041526306337383563735515E+52
2.658271574788448768043627E+54
1.196222208654801945619632E+56
5.502622159812088949850307E+57
2.586232415111681806429644E+59
1.241391559253607267086229E+61
6.082818640342675608722522E+62

``````

The value of e is

``````1
2
2.5
2.666666666666666666666667
2.708333333333333333333334
2.716666666666666666666667
2.718055555555555555555556
2.718253968253968253968254
2.718278769841269841269841
2.718281525573192239858906
2.718281801146384479717813
2.718281826198492865159532
2.718281828286168563946342
2.718281828446759002314558
2.718281828458229747912288
2.718281828458994464285470
2.718281828459042259058794
2.718281828459045070516048
2.718281828459045226708118
2.718281828459045234928753
2.718281828459045235339785
2.718281828459045235359358
2.718281828459045235360248
2.718281828459045235360287
2.718281828459045235360289
2.718281828459045235360289
...
``````