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We are supposed to calculate e^x using this kind of formula:

e^x = 1 + (x ^ 1 / 1!) + (x ^ 2 / 2!) ......

I have this code so far:

while (result >= 1.0E-20 )
{
    power = power * input;
    factorial = factorial * counter;
    result = power / factorial;
    eValue += result;
    counter++;
    iterations++;
}

My problem now is that since factorial is of type long long, I can't really store a number greater than 20! so what happens is that the program outputs funny numbers when it reaches that point ..

The correct solution can have an X value of at most 709 so e^709 should output: 8.21840746155e+307

The program is written in C++.

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1  
why not make factorial a double? –  Nathan Fellman Sep 23 '09 at 11:57
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4 Answers

up vote 31 down vote accepted

Both x^n and n! quickly grow large with n (exponentially and superexponentially respectively) and will soon overflow any data type you use. On the other hand, x^n/n! goes down (eventually) and you can stop when it's small. That is, use the fact that x^(n+1)/(n+1)! = (x^n/n!) * (x/(n+1)). Like this, say:

term = 1.0;
for(n=1; term >= 1.0E-10; n++)
{
    eValue += term;
    term = term * x / n;
}

(Code typed directly into this box, but I expect it should work.)

Edit: Note that the term x^n/n! is, for large x, increasing for a while and then decreasing. For x=709, it goes up to ~1e+306 before decreasing to 0, which is just at the limits of what double can handle (double's range is ~1e308 and term*x pushes it over), but long double works fine. Of course, your final result ex is larger than any of the terms, so assuming you're using a data type big enough to accommodate the result, you'll be fine.

(For x=709, you can get away with using just double if you use term = term / n * x, but it doesn't work for 710.)

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+1: Beat me to it! –  gnovice May 6 '09 at 2:14
    
Sorry for being dense but I can't get it .. When I substitute X with 709, the answer is 1.8046..e+016 –  Charles Khunt May 6 '09 at 2:20
    
Yeah, I added a note to the answer to address this. x=709 is at the limits of what double can handle. –  ShreevatsaR May 6 '09 at 2:48
1  
The math is not too much :) The terms are 1, x/1, x*x/(1*2), x*x*x/(1*2*3), x*x*x*x/(1*2*3*4), and so on. That is, the x^2/2! term is (x/2) times the x^1/1! term, the x^3/3! term is (x/3) times the x^2/2! term, etc. In general, x^n = x^(n-1)*x and n!=(n-1)!*n (this is by definition of the factorial), so x^n/n! = x^(n-1)*x/((n-1)!*n) = [x^(n-1)/(n-1)!] * (x/n). That is, the x^n/n! term is x/n times the previous term. –  ShreevatsaR May 6 '09 at 4:15
1  
Or, to put it differently -- your code had "power = power * input; factorial = factorial * counter; result = power / factorial;" while mine just has "result = result * input / counter;". Same thing. –  ShreevatsaR May 6 '09 at 4:22
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What happens if you change the type of factorial from long long to double?

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trying to calculate e^709 with factorial of type double produced: -1.#IND And the max iteration i guess is 172 –  Charles Khunt May 6 '09 at 2:10
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I can think of another solution. Let pow(e,x) = pow(10, m) * b where b is >=1 and < 10, then

m = trunc( x * log10(e) )

where in log10(e) is a constant factor.

and

b = pow(e,x)/pow(10, m ) = pow(e,x)/pow(e,m/log10(e)) = pow (e,x-m/log10(e))

By this you get:

z = x-m/log10(e)

which will be in between 0 to 3 and then use b = pow(e,z) as given by SreevartsR.

and final answer is

b is base(significant digit) and m is mantissa (order of magnitude).

this will be faster than SreevartsR approach and you might not need to use high precisions.

Best of luck.

This will even work for when x is less than 0 and a bigger negative, in that case z will be in between 0 to -3 and this will be faster than any other approach.

Since z is -3 to 3, and if you require first 20 significant digits, then pow(e,z) expression can be evaluated upto 37 terms only since 3^37/37! = ~ 3.2e-26.

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Certainly it will be faster – even faster would be to write exp(x) — but it doesn't satisfy the requirement of "calculating e^x without using any functions". :-) –  ShreevatsaR Feb 19 '10 at 13:18
    
@ShreevatsaR: Actually, I think it does - even though I can't see any advantage from calculating in base-10. Where does this solution use any functions? –  jpalecek Jul 20 '10 at 19:48
    
@jpalecek: pow() is an inbuilt function, just like exp(). I assume the intent of the original poster was precisely not to use exp() or other such functions (or even, perhaps, the intent was to use the given series). –  ShreevatsaR Jul 20 '10 at 22:51
    
@ShreevatsaR: You cannot do pow(10, integer) without actually calling std::pow? It seems like a kindergarten task for me... –  jpalecek Jul 21 '10 at 1:02
1  
@ShreevatsaR: Yes - sort of. The point is, Taylor series converges faster in the neighbourhood of zero (and uniformly on any disc around zero) so it's easier to compute (compare your "largest term" which is the 700th with the 37 terms stated here). –  jpalecek Jul 21 '10 at 9:40
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What you presented here is an application of Horner scheme to calculate polynomials.

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