Martingale (probability theory)
In probability theory, a martingale is a model of a fair game where knowledge of past events never helps predict the mean of the future winnings. In particular, a martingale is a sequence of random variables (i.e., a stochastic process) for which, at a particular time in the realized sequence, the expectation of the next value in the sequence is equal to the present observed value even given knowledge of all prior observed values.
To contrast, in a process that is not a martingale, it may still be the case that the expected value of the process at one time is equal to the expected value of the process at the next time. However, knowledge of the prior outcomes (e.g., all prior cards drawn from a card deck) may be able to reduce the uncertainty of future outcomes. Thus, the expected value of the next outcome given knowledge of the present and all prior outcomes may be higher than the current outcome if a winning strategy is used. Martingales exclude the possibility of winning strategies based on game history, and thus they are a model of fair games.
Contents
History
Originally, martingale referred to a class of betting strategies that was popular in 18thcentury France.^{[1]}^{[2]} The simplest of these strategies was designed for a game in which the gambler wins his stake if a coin comes up heads and loses it if the coin comes up tails. The strategy had the gambler double his bet after every loss so that the first win would recover all previous losses plus win a profit equal to the original stake. As the gambler's wealth and available time jointly approach infinity, his probability of eventually flipping heads approaches 1, which makes the martingale betting strategy seem like a sure thing. However, the exponential growth of the bets eventually bankrupts its users, assuming the obvious and realistic finite bankrolls (one of the reasons casinos, though normatively enjoying a mathematical edge in the games offered to their patrons, impose betting limits). Stopped Brownian motion, which is a martingale process, can be used to model the trajectory of such games.
The concept of martingale in probability theory was introduced by Paul Lévy in 1934, though he did not name them: the term "martingale" was introduced later by Ville (1939), who also extended the definition to continuous martingales. Much of the original development of the theory was done by Joseph Leo Doob among others. Part of the motivation for that work was to show the impossibility of successful betting strategies.
Definitions
A basic definition of a discretetime martingale is a discretetime stochastic process (i.e., a sequence of random variables) X_{1}, X_{2}, X_{3}, ... that satisfies for any time n,
That is, the conditional expected value of the next observation, given all the past observations, is equal to the last observation. Due to the linearity of expectation, this second requirement is equivalent to:
 or
which states that the average "winnings" from observation to observation are 0.
Martingale sequences with respect to another sequence
More generally, a sequence Y_{1}, Y_{2}, Y_{3} ... is said to be a martingale with respect to another sequence X_{1}, X_{2}, X_{3} ... if for all n
Similarly, a continuoustime martingale with respect to the stochastic process X_{t} is a stochastic process Y_{t} such that for all t
This expresses the property that the conditional expectation of an observation at time t, given all the observations up to time , is equal to the observation at time s (of course, provided that s ≤ t).
General definition
In full generality, a stochastic process is a martingale with respect to a filtration and probability measure P if
 Σ_{∗} is a filtration of the underlying probability space (Ω, Σ, P);
 Y is adapted to the filtration Σ_{∗}, i.e., for each t in the index set T, the random variable Y_{t} is a Σ_{t}measurable function;
 for each t, Y_{t} lies in the L^{p} space L^{1}(Ω, Σ_{t}, P; S), i.e.
 for all s and t with s < t and all F ∈ Σ_{s},

 where χ_{F} denotes the indicator function of the event F. In Grimmett and Stirzaker's Probability and Random Processes, this last condition is denoted as
 which is a general form of conditional expectation.^{[3]}
It is important to note that the property of being a martingale involves both the filtration and the probability measure (with respect to which the expectations are taken). It is possible that Y could be a martingale with respect to one measure but not another one; the Girsanov theorem offers a way to find a measure with respect to which an Itō process is a martingale.
Examples of martingales
 An unbiased random walk (in any number of dimensions) is an example of a martingale.
 A gambler's fortune (capital) is a martingale if all the betting games which the gambler plays are fair.
 Polya's urn contains a number of different coloured marbles, and each iteration a marble is randomly selected out of the urn and replaced with several more of that same colour. For any given colour, the ratio of marbles inside the urn with that colour is a martingale. For example, if currently 95% of the marbles are red then—though the next iteration is much more likely add more red marbles—this bias is exactly balanced out by the fact that adding more red marbles alters the ratio much less significantly than adding the same number of nonred marbles would.
 Suppose X_{n} is a gambler's fortune after n tosses of a fair coin, where the gambler wins $1 if the coin comes up heads and loses $1 if the coin comes up tails. The gambler's conditional expected fortune after the next trial, given the history, is equal to his present fortune, so this sequence is a martingale.
 Let Y_{n} = X_{n}^{2} − n where X_{n} is the gambler's fortune from the preceding example. Then the sequence { Y_{n} : n = 1, 2, 3, ... } is a martingale. This can be used to show that the gambler's total gain or loss varies roughly between plus or minus the square root of the number of steps.
 (de Moivre's martingale) Now suppose an "unfair" or "biased" coin, with probability p of "heads" and probability q = 1 − p of "tails". Let

 with "+" in case of "heads" and "−" in case of "tails". Let
 Then { Y_{n} : n = 1, 2, 3, ... } is a martingale with respect to { X_{n} : n = 1, 2, 3, ... }. To show this
 (Likelihoodratio testing in statistics) A population is thought to be distributed according to either a probability density f or another probability density g. A random sample is taken, the data being X_{1}, ..., X_{n}. Let Y_{n} be the "likelihood ratio"
 (which, in applications, would be used as a test statistic). If the population is actually distributed according to the density f rather than according to g, then { Y_{n} : n = 1, 2, 3, ... } is a martingale with respect to { X_{n} : n = 1, 2, 3, ... }.
 Suppose each amoeba either splits into two amoebas, with probability p, or eventually dies, with probability 1 − p. Let X_{n} be the number of amoebas surviving in the nth generation (in particular X_{n} = 0 if the population has become extinct by that time). Let r be the probability of eventual extinction. (Finding r as function of p is an instructive exercise. Hint: The probability that the descendants of an amoeba eventually die out is equal to the probability that either of its immediate offspring dies out, given that the original amoeba has split.) Then
 is a martingale with respect to { X_{n}: n = 1, 2, 3, ... }.
 In an ecological community (a group of species that are in a particular trophic level, competing for similar resources in a local area), the number of individuals of any particular species of fixed size is a function of (discrete) time, and may be viewed as a sequence of random variables. This sequence is a martingale under the unified neutral theory of biodiversity and biogeography.
 If { N_{t} : t ≥ 0 } is a Poisson process with intensity λ, then the compensated Poisson process { N_{t} − λt : t ≥ 0 } is a continuoustime martingale with rightcontinuous/leftlimit sample paths.
Submartingales, supermartingales, and relationship to harmonic functions
There are two popular generalizations of a martingale that also include cases when the current observation X_{n} is not necessarily equal to the future conditional expectation E[X_{n+1}X_{1},...,X_{n}] but instead an upper or lower bound on the conditional expectation. These definitions reflect a relationship between martingale theory and potential theory, which is the study of harmonic functions. Just as a continuoustime martingale satisfies E[X_{t}{X_{τ} : τ≤s}] − X_{s} = 0 ∀s ≤ t, a harmonic function f satisfies the partial differential equation Δf = 0 where Δ is the Laplacian operator. Given a Brownian motion process W_{t} and a harmonic function f, the resulting process f(W_{t}) is also a martingale.
 A discretetime submartingale is a sequence of integrable random variables satisfying

 Likewise, a continuoustime submartingale satisfies
 In potential theory, a subharmonic function f satisfies Δf ≥ 0. Any subharmonic function that is bounded above by a harmonic function for all points on the boundary of a ball are bounded above by the harmonic function for all points inside the ball. Similarly, if a submartingale and a martingale have equivalent expectations for a given time, the history of the submartingale tends to be bounded above by the history of the martingale. Roughly speaking, the prefix "sub" is consistent because the current observation X_{n} is less than (or equal to) the conditional expectation E[X_{n}_{+1}X_{1},...,X_{n}]. Consequently, the current observation provides support from below the future conditional expectation, and the process tends to increase in future time.
 Analogously, a discretetime supermartingale satisfies

 Likewise, a continuoustime supermartingale satisfies
 In potential theory, a superharmonic function f satisfies Δf ≤ 0. Any superharmonic function that is bounded below by a harmonic function for all points on the boundary of a ball are bounded below by the harmonic function for all points inside the ball. Similarly, if a supermartingale and a martingale have equivalent expectations for a given time, the history of the supermartingale tends to be bounded below by the history of the martingale. Roughly speaking, the prefix "super" is consistent because the current observation X_{n} is greater than (or equal to) the conditional expectation E[X_{n}_{+1}X_{1},...,X_{n}]. Consequently, the current observation provides support from above the future conditional expectation, and the process tends to decrease in future time.
Examples of submartingales and supermartingales
 Every martingale is also a submartingale and a supermartingale. Conversely, any stochastic process that is both a submartingale and a supermartingale is a martingale.
 Consider again the gambler who wins $1 when a coin comes up heads and loses $1 when the coin comes up tails. Suppose now that the coin may be biased, so that it comes up heads with probability p.
 If p is equal to 1/2, the gambler on average neither wins nor loses money, and the gambler's fortune over time is a martingale.
 If p is less than 1/2, the gambler loses money on average, and the gambler's fortune over time is a supermartingale.
 If p is greater than 1/2, the gambler wins money on average, and the gambler's fortune over time is a submartingale.
 A convex function of a martingale is a submartingale, by Jensen's inequality. For example, the square of the gambler's fortune in the fair coin game is a submartingale (which also follows from the fact that X_{n}^{2} − n is a martingale). Similarly, a concave function of a martingale is a supermartingale.
Martingales and stopping times
A stopping time with respect to a sequence of random variables X_{1}, X_{2}, X_{3}, ... is a random variable τ with the property that for each t, the occurrence or nonoccurrence of the event τ = t depends only on the values of X_{1}, X_{2}, X_{3}, ..., X_{t}. The intuition behind the definition is that at any particular time t, you can look at the sequence so far and tell if it is time to stop. An example in real life might be the time at which a gambler leaves the gambling table, which might be a function of his previous winnings (for example, he might leave only when he goes broke), but he can't choose to go or stay based on the outcome of games that haven't been played yet.
In some contexts the concept of stopping time is defined by requiring only that the occurrence or nonoccurrence of the event τ = t be probabilistically independent of X_{t + 1}, X_{t + 2}, ... but not that it be completely determined by the history of the process up to time t. That is a weaker condition than the one appearing in the paragraph above, but is strong enough to serve in some of the proofs in which stopping times are used.
One of the basic properties of martingales is that, if is a (sub/super) martingale and is a stopping time, then the corresponding stopped process defined by is also a (sub/super) martingale.
The concept of a stopped martingale leads to a series of important theorems, including, for example, the optional stopping theorem which states that, under certain conditions, the expected value of a martingale at a stopping time is equal to its initial value.
See also
Notes
 ↑ Balsara, N. J. (1992). Money Management Strategies for Futures Traders. Wiley Finance. p. 122. ISBN 0471522155.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
 ↑ Mansuy, Roger (June 2009). "The origins of the Word "Martingale"" (PDF). Electronic Journal for History of Probability and Statistics. 5 (1). Retrieved 20111022.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
 ↑ Grimmett, G.; Stirzaker, D. (2001). Probability and Random Processes (3rd ed.). Oxford University Press. ISBN 0198572239.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
References
 Hazewinkel, Michiel, ed. (2001), "Martingale", Encyclopedia of Mathematics, Springer, ISBN 9781556080104<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
 "The Splendors and Miseries of Martingales". Electronic Journal for History of Probability and Statistics. 5 (1). June 2009.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles> Entire issue dedicated to Martingale probability theory.
 Williams, David (1991). Probability with Martingales. Cambridge University Press. ISBN 0521406056.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
 Kleinert, Hagen (2004). Path Integrals in Quantum Mechanics, Statistics, Polymer Physics, and Financial Markets (4th ed.). Singapore: World Scientific. ISBN 9812381074.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
 Siminelakis, Paris (2010). "Martingales and Stopping Times: Use of martingales in obtaining bounds and analyzing algorithms" (PDF). University of Athens.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
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