Probabilistic method
In mathematics, the probabilistic method is a nonconstructive method, primarily used in combinatorics and pioneered by Paul Erdős, for proving the existence of a prescribed kind of mathematical object. It works by showing that if one randomly chooses objects from a specified class, the probability that the result is of the prescribed kind is strictly greater than zero. Although the proof uses probability, the final conclusion is determined for certain, without any possible error.
This method has now been applied to other areas of mathematics such as number theory, linear algebra, and real analysis, as well as in computer science (e.g. randomized rounding), and information theory.
Introduction
If every object in a collection of objects fails to have a certain property, then the probability that a random object chosen from the collection has that property is zero.
Similarly, showing that the probability is (strictly) less than 1 can be used to prove the existence of an object that does not satisfy the prescribed properties.
Another way to use the probabilistic method is by calculating the expected value of some random variable. If it can be shown that the random variable can take on a value less than the expected value, this proves that the random variable can also take on some value greater than the expected value.
Alternatively, the probabilistic method can also be used to guarantee the existence of a desired element in a sample space with a value that is greater than or equal to the calculated expected value, since the non-existence of such element would imply every element in the sample space is less than the expected value, a contradiction.
Common tools used in the probabilistic method include Markov's inequality, the Chernoff bound, and the Lovász local lemma.
Two examples due to Erdős
Although others before him proved theorems via the probabilistic method (for example, Szele's 1943 result that there exist tournaments containing a large number of Hamiltonian cycles), many of the most well known proofs using this method are due to Erdős. The first example below describes one such result from 1947 that gives a proof of a lower bound for the Ramsey number R(r, r).
First example
Suppose we have a complete graph on n vertices. We wish to show (for small enough values of n) that it is possible to color the edges of the graph in two colors (say red and blue) so that there is no complete subgraph on r vertices which is monochromatic (every edge colored the same color).
To do so, we color the graph randomly. Color each edge independently with probability 1/2 of being red and 1/2 of being blue. We calculate the expected number of monochromatic subgraphs on r vertices as follows:
For any set of vertices from our graph, define the variable to be 1 if every edge amongst the vertices is the same color, and 0 otherwise. Note that the number of monochromatic -subgraphs is the sum of over all possible subsets . For any individual set , the expected value of is simply the probability that all of the edges in are the same color:
(the factor of 2 comes because there are two possible colors).
This holds true for any of the possible subsets we could have chosen, i.e. ranges from 1 to . So we have that the sum of over all is
The sum of expectations is the expectation of the sum (regardless of whether the variables are independent), so the expectation of the sum (the expected number of all monochromatic -subgraphs) is
Consider what happens if this value is less than 1. Since the expected number of monochromatic r-subgraphs is strictly less than 1, there exists a coloring satisfying the condition that the number of monochromatic r-subgraphs is strictly less than 1. The number of monochromatic r-subgraphs in this random coloring is a non-negative integer, hence it must be 0 (0 is the only non-negative integer less than 1). It follows that if
(which holds, for example, for n = 5 and r = 4), there must exist a coloring in which there are no monochromatic r-subgraphs.[a]
By definition of the Ramsey number, this implies that R(r, r) must be bigger than n. In particular, R(r, r) must grow at least exponentially with r.
A weakness of this argument is that it is entirely nonconstructive. Even though it proves (for example) that almost every coloring of the complete graph on (1.1)r vertices contains no monochromatic r-subgraph, it gives no explicit example of such a coloring. The problem of finding such a coloring has been open for more than 50 years.
- ^
The same fact can be proved without probability, using a simple counting argument:
- The total number of r-subgraphs is .
- Each r-subgraphs has edges and thus can be colored in different ways.
- Of these colorings, only 2 colorings are 'bad' for that subgraph (the colorings in which all vertices are red or all vertices are blue).
- Hence, the total number of colorings that are bad for some (at least one) subgraph is at most .
- Hence, if , there must be at least one coloring which is not 'bad' for any subgraph.
- )
See also
- Interactive proof system
- Las Vegas algorithm
- Incompressibility method
- Method of conditional probabilities
- Probabilistic proofs of non-probabilistic theorems
- Random graph
Additional resources
- Probabilistic Methods in Combinatorics, MIT OpenCourseWare
References
- Alon, Noga; Spencer, Joel H. (2000). The probabilistic method (2ed). New York: Wiley-Interscience. ISBN 0-471-37046-0.
- Erdős, P. (1959). "Graph theory and probability". Can. J. Math. 11: 34–38. doi:10.4153/CJM-1959-003-9. MR 0102081. S2CID 122784453.
- Erdős, P. (1961). "Graph theory and probability, II". Can. J. Math. 13: 346–352. CiteSeerX 10.1.1.210.6669. doi:10.4153/CJM-1961-029-9. MR 0120168. S2CID 15134755.
- J. Matoušek, J. Vondrak. The Probabilistic Method. Lecture notes.
- Alon, N and Krivelevich, M (2006). Extremal and Probabilistic Combinatorics
- Elishakoff I., Probabilistic Methods in the Theory of Structures: Random Strength of Materials, Random Vibration, and Buckling, World Scientific, Singapore, ISBN 978-981-3149-84-7, 2017
- Elishakoff I., Lin Y.K. and Zhu L.P., Probabilistic and Convex Modeling of Acoustically Excited Structures, Elsevier Science Publishers, Amsterdam, 1994, VIII + pp. 296; ISBN 0 444 81624 0