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Show Source |    | About   «  24.3. The Fast Fourier Transform   ::   Contents   ::   25.2. Finding Prime Numbers  »

25.1. Introduction to Probabilistic Algorithms

25.1.1. Probabilistic Algorithms

We now consider how introducing randomness into our algorithms might speed things up, although perhaps at the expense of accuracy. But often we can reduce the possibility for error to be as low as we like, while still speeding up the algorithm.

The lower bound for maximum finding in an unsorted list is \(\Omega(n)\). This is the least time needed to be certain that we have found the maximum value. But what if we are willing to relax our requirement for certainty? The first question is: What do we mean by this? There are many aspects to “certainty” and we might relax the requirement in various ways.

There are several possible guarantees that we might require from an algorithm that produces \(X\) as the maximum value, when the true maximum is \(Y\).

  • So far we have assumed that we require \(X\) to equal \(Y\). This is known as an exact or deterministic algorithm to solve the problem.

  • We could relax this and require only that \(X\) ‘s rank is “close to” \(Y\) ‘s rank (perhaps within a fixed distance or percentage). This is known as an approximation algorithm.

  • We could require that \(X\) is “usually” \(Y\). This is known as a probabilistic algorithm.

  • Finally, we could require only that \(X\) ‘s rank is “usually” “close” to \(Y\) ‘s rank. This is known as a heuristic algorithm.

There are also different ways that we might choose to sacrifice reliability for speed. These types of algorithms also have names.

  1. Las Vegas Algorithms: We always find the maximum value, and “usually” we find it fast. Such algorithms have a guaranteed result, but do not guarantee fast running time.

  2. Monte Carlo Algorithms: We find the maximum value fast, or we don’t get an answer at all (but fast). While such algorithms have good running time, their result is not guaranteed.

Here is an example of an algorithm for finding a large value that gives up its guarantee of getting the best value in exchange for an improved running time. This is an example of a probabilistic algorithm, since it includes steps that are affected by random events. Choose \(m\) elements at random, and pick the best one of those as the answer. For large \(n\), if \(m \approx \log n\), the answer is pretty good. The cost is \(m-1\) compares (since we must find the maximum of \(m\) values). But we don’t know for sure what we will get. However, we can estimate that the rank will be about \(\frac{mn}{m+1}\). For example, if \(n = 1,000,000\) and \(m = \log n = 20\), then we expect that the largest of the 20 randomly selected values be among the top 5% of the \(n\) values.

Next, consider a slightly different problem where the goal is to pick a number in the upper half of \(n\) values. We would pick the maximum from among the first \(\frac{n+1}{2}\) values for a cost of \(n/2\) comparisons. Can we do better than this? Not if we want to guarantee getting the correct answer. But if we are willing to accept near certainty instead of absolute certainty, we can gain a lot in terms of speed.

As an alternative, consider this probabilistic algorithm. Pick 2 numbers and choose the greater. This will be in the upper half with probability 3/4 (since it is not in the upper half only when both numbers we choose happen to be in the lower half). Is a probability of 3/4 not good enough? Then we simply pick more numbers! For \(k\) numbers, the greatest is in upper half with probability \(1 - \frac{1}{2^k}\), regardless of the number \(n\) that we pick from, so long as \(n\) is much larger than \(k\) (otherwise the chances might become even better). If we pick ten numbers, then the chance of failure is only one in \(2^{10} = 1024\). What if we really want to be sure, because lives depend on drawing a number from the upper half? If we pick 30 numbers, we can fail only one time in a billion. If we pick enough numbers, then the chance of picking a small number is less than the chance of the power failing during the computation. Picking 100 numbers means that we can fail only one time in \(10^{100}\) which is less than the chance any plausible disaster that you can imagine will disrupt the process.

   «  24.3. The Fast Fourier Transform   ::   Contents   ::   25.2. Finding Prime Numbers  »

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