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Conceptually, I need to multiply the probabilities of each event in a coincidence. Since there may be very many events involved, I have the computer add the logarithms to avoid underflow.

But suddenly I can't convince myself that I should initialize the return value to zero before I start adding. I know zero is the identity element for addition, and I remember this is how I do it, but, looking at a graph of the logarithm, I can clearly see that the antilog of zero is negative infinity.

So initializing the return value to zero should be equivalent to multiplying all my probabilities by negative infinity, which is definitely not correct. What am I doing wrong?

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closed as off topic by Jens Björnhager, Ken Fyrstenberg, Marek Grzenkowicz, Arun P Johny, EladN Jan 7 '13 at 11:52

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You should ask this at math.stackexchange.com –  gnibbler Feb 11 '11 at 12:09
    
Not really - this is simple high school math. –  duffymo Feb 11 '11 at 12:11
    
What that graph is saying is a different thing from what you can "clearly see" on it :) –  AakashM Feb 11 '11 at 12:14
    
The behavior of the graph at x = 0 is irrelevant. He's not concerned about x = 0; he cares about ln(x) = 0. That's what he's summing. And ln(x) = 0 means that x = 1. –  duffymo Feb 11 '11 at 12:21

3 Answers 3

up vote 6 down vote accepted

The antilog of zero is one, not negative infinity. That means that starting adding with zero for the logarithm is the same as starting multiplying with one for the probabilities themselves.

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Oh, you're right! The antilog of zero is not negative infinity. The antilog of negative infinity is zero. I've been misreading the axes on this graph for like fifteen minutes. –  Wang Feb 11 '11 at 12:06
    
Sorry but lim log(x) as x->0 is - ininity. –  rmarimon Feb 11 '11 at 12:07
    
He's not taking anti-logs; this answer isn't correct. –  duffymo Feb 11 '11 at 12:09
    
@rmarimon But x->0 isn't what's in question. He's adding the logarithms, which means log x -> 0 is the question. –  Michael J. Barber Feb 11 '11 at 12:11
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@duffymo - Your answer is correct, but so is this one. In fact they say the same thing. –  Don Roby Feb 11 '11 at 12:26

If you are multiplying values together, they look like this:

product = 1*p1*....*pn

If you take the natural log of both sides it looks like this:

ln(product) = ln(1) + ln(p1) + .... + ln(pn)

But ln(1) = 0, so that's how you initialize the sum of logarithms. Set it to zero.

Remember what you're summing here: the log of each probability adds into the log of the total probability. Once you complete the sum, you can get the product like this:

product = exp(ln(product)) = exp(ln(sum of ln(pn))
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product = exp(ln(product)) = exp(sum of ln(pn)) is enough :-) –  Emmanuel Feb 11 '11 at 13:34
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I thought remedial readers might appreciate the other lines as well. –  duffymo Feb 11 '11 at 15:21

If you are calculating the intersection of events. Just multiply them. No need to take into logarithmic space. If it gets really really small then is zero probability for the intersection of events.

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1  
If you're calculating a conditional probability, it is very easy to get ratios of numbers that are each so small that round off errors will kill you. The log approach avoids that issues. –  btilly Feb 11 '11 at 19:05

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