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! Approximation
! Approximation
! Range of possible values for the actual count
! Range of possible values for the actual count
! Expectation (sufficiently large n, uniform distribution)
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If the counter holds the value of 101, which equates to an exponent of 5 (the decimal equivalent of 101), then the estimated count is 2^5, or 32. There is a very low probability that the actual count of increment events was 5 (which would imply that an extremely rare event occurred with the pseudo-random number generator, the same probability as getting 10 consecutive heads in 10 coin flips). The actual count of increment events is likely to be around 32, but it could be infinitely high (with decreasing probabilities for actual counts above 32).
If the counter holds the value of 101, which equates to an exponent of 5 (the decimal equivalent of 101), then the estimated count is 2^5, or 32. There is a fairly low probability that the actual count of increment events was 5 (<math>\frac{1}{1024} = 1 \times \frac{1}{2} \times \frac{1}{4} \times \frac{1}{8} \times \frac{1}{16}</math>). The actual count of increment events is likely to be "around 32", but it could be arbitrarily high (with decreasing probabilities for actual counts above 39).


=== Selecting counter values ===
=== Selecting counter values ===

Revision as of 16:48, 17 October 2018

The approximate counting algorithm allows the counting of a large number of events using a small amount of memory. Invented in 1977 by Robert Morris (cryptographer) of Bell Labs, it uses probabilistic techniques to increment the counter. It was fully analyzed in the early 1980s by Philippe Flajolet of INRIA Rocquencourt, who coined the name approximate counting, and strongly contributed to its recognition among the research community. The algorithm is considered one of the precursors of streaming algorithms, and the more general problem of determining the frequency moments of a data stream has been central to the field.

Theory of operation

Using Morris' algorithm, the counter represents an "order of magnitude estimate" of the actual count. The approximation is mathematically unbiased.

To increment the counter, a pseudo-random event is used, such that the incrementing is a probabilistic event. To save space, only the exponent is kept. For example, in base 2, the counter can estimate the count to be 1, 2, 4, 8, 16, 32, and all of the powers of two. The memory requirement is simply to hold the exponent.

As an example, to increment from 4 to 8, a pseudo-random number would be generated such that a probability of .25 generates a positive change in the counter. Otherwise, the counter remains at 4.

The table below illustrates some of the potential values of the counter:

Stored binary value of counter Approximation Range of possible values for the actual count Expectation (sufficiently large n, uniform distribution)
0 1 0, or initial value 0
1 2 1 or more 2
10 4 2 or more 6
11 8 3 or more 14
100 16 4 or more 30
101 32 5 or more 62

If the counter holds the value of 101, which equates to an exponent of 5 (the decimal equivalent of 101), then the estimated count is 2^5, or 32. There is a fairly low probability that the actual count of increment events was 5 (). The actual count of increment events is likely to be "around 32", but it could be arbitrarily high (with decreasing probabilities for actual counts above 39).

Selecting counter values

While using powers of 2 as counter values is memory efficient, arbitrary values tend to create a dynamic error range, and the smaller values will have a greater error ratio than bigger values. Other methods of selecting counter values consider parameters such as memory availability, desired error ratio, or counting range to provide an optimal set of values.[1]

Algorithm

When incrementing the counter, "flip a coin" the number of times of the counter's current value. If it comes up "Heads" each time, then increment the counter. Otherwise, do not increment it.

This can be done programmatically by generating "c" pseudo-random bits (where "c" is the current value of the counter), and using the logical AND function on all of those bits. The result is a zero if any of those pseudo-random bits are zero, and a one if they are all ones. Simply add the result to the counter. This procedure is executed each time the request is made to increment the counter.

Applications

The algorithm is useful in examining large data streams for patterns. This is particularly useful in applications of data compression, sight and sound recognition, and other artificial intelligence applications.

References

  1. ^ Tsidon, Erez, Iddo Hanniel, and Isaac Keslassy. "Estimators also need shared values to grow together." INFOCOM, 2012 Proceedings IEEE. IEEE, 2012.

Sources

  • Morris, R. Counting large numbers of events in small registers. Communications of the ACM 21, 10 (1977), 840–842
  • Flajolet, P. Approximate Counting: A Detailed Analysis. BIT 25, (1985), 113–134 [1]
  • Michael F., Chung-Kuei L., Prodinger, Approximate Counting via the Poisson-Laplace-Mellin Method [2]