In mathematics, Doob's martingale inequality, also known as Kolmogorov’s submartingale inequality is a result in the study of stochastic processes. It gives a bound on the probability that a submartingale exceeds any given value over a given interval of time. As the name suggests, the result is usually given in the case that the process is a martingale, but the result is also valid for submartingales.
The inequality is due to the American mathematician Joseph L. Doob.
The setting of Doob's inequality is a submartingale relative to a filtration of the underlying probability space. The probability measure on the sample space of the martingale will be denoted by . The corresponding expected value of a random variable, as defined by Lebesgue integration, will be denoted by .
Informally, Doob's inequality states that the expected value of the process at some final time controls the probability that a sample path will reach above any particular value beforehand. As the proof uses very direct reasoning, it does not require any restrictive assumptions on the underlying filtration or on the process itself, unlike for many other theorems about stochastic processes. In the continuous-time setting, right-continuity (or left-continuity) of the sample paths is required, but only for the sake of knowing that the supremal value of a sample path equals the supremum over an arbitrary countable dense subset of times.
Let be a discrete-time submartingale relative to a filtration
l{F}1,\ldots,l{F}n
Xi\leq\operatornameE[Xi+1\midl{F}i].
P\left[max1Xi\geqC\right]\leq
| \operatornameE[rm{max | |
| (X |
n,0)]}{C}
CP(Ei)=
| \int | |
| Ei |
CdP\leq
| \int | |
| Ei |
XidP\leq\int
| Ei |
E[Xn\midl{F}i]dP=\int
| Ei |
XndP,
Ei\inl{F}i
CP(E)\leq\intEXndP,
In this proof, the submartingale property is used once, together with the definition of conditional expectation. The proof can also be phrased in the language of stochastic processes so as to become a corollary of the powerful theorem that a stopped submartingale is itself a submartingale. In this setup, the minimal index appearing in the above proof is interpreted as a stopping time.
Now let be a submartingale indexed by an interval of real numbers, relative to a filtration of the underlying probability space, which is to say:
Xs\leq\operatornameE[Xt\midl{F}s].
P\left[\sup0Xt\geqC\right]\leq
| \operatornameE[rm{max | |
| (X |
T,0)]}{C}
\sup0\leqXt=\sup\{Xt:t\in[0,T]\capQ\}=\limi\toinfty\sup\{Xt:t\in[0,T]\capQi\}
P\left[
| \sup | |
| t\in[0,T]\capQi |
Xt\geqC\right]\leq
| \operatornameE[rm{max | |
| (X |
T,0)]}{C}
There are further submartingale inequalities also due to Doob. Now let be a martingale or a positive submartingale; if the index set is uncountable, then (as above) assume that the sample paths are right-continuous. In these scenarios, Jensen's inequality implies that is a submartingale for any number, provided that these new random variables all have finite integral. The submartingale inequality is then applicable to say that
P[\supt|Xt|\geqC]\leq
| |||||||
| Cp |
.
E[|XT|p]\leqE\left[\sup0
| p\right] | |
| |X | |
| s| |
\leq\left(
| p | |
| p-1 |
| p] | |
| \right) | |
| T| |
In addition to the above inequality, there holds
E\left|\sup0Xs\right|\leq
| e | |
| e-1 |
\left(1+E[max\{|XT|log|XT|,0\}]\right)
Doob's inequality for discrete-time martingales implies Kolmogorov's inequality: if X1, X2, ... is a sequence of real-valued independent random variables, each with mean zero, it is clear that
\begin{align} \operatornameE\left[X1+ … +Xn+Xn\midX1,\ldots,Xn\right]&=X1+ … +Xn+\operatornameE\left[Xn\midX1,\ldots,Xn\right]\\ &=X1+ … +Xn, \end{align}
so Sn = X1 + ... + Xn is a martingale. Note that Jensen's inequality implies that |Sn| is a nonnegative submartingale if Sn is a martingale. Hence, taking p = 2 in Doob's martingale inequality,
P\left[max1\left|Si\right|\geqλ\right]\leq
| |||||||||
| λ2 |
,
which is precisely the statement of Kolmogorov's inequality.
Let B denote canonical one-dimensional Brownian motion. Then
P\left[\sup0Bt\geqC\right]\leq\exp\left(-
| C2 | |
| 2T |
\right).
The proof is just as follows: since the exponential function is monotonically increasing, for any non-negative λ,
\left\{\sup0Bt\geqC\right\}=\left\{\sup0\exp(λBt)\geq\exp(λC)\right\}.
By Doob's inequality, and since the exponential of Brownian motion is a positive submartingale,
\begin{align} P\left[\sup0Bt\geqC\right]&=P\left[\sup0\exp(λBt)\geq\exp(λC)\right]\\[8pt] &\leq
| \operatornameE[\exp(λBT)] | |
| \exp(λC) |
\\[8pt] &=\exp\left(\tfrac{1}{2}λ2T-λC\right)&&\operatornameE\left[\exp(λBt)\right]=\exp\left(\tfrac{1}{2}λ2t\right) \end{align}
Since the left-hand side does not depend on λ, choose λ to minimize the right-hand side: λ = C/T gives the desired inequality.
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