Let X₁, ..., X_n : Ω → R be independent random variables defined on a common probability space (Ω, F, Pr), with expected value E[X_k] = 0 and variance Var[X_k] < +∞ for k = 1, ..., n. Then, for each λ > 0,

${\displaystyle \Pr \left(\max _{1\leq k\leq n}|S_{k}|\geq \lambda \right)\leq {\frac {1}{\lambda ^{2}}}\operatorname {Var} [S_{n}]\equiv {\frac {1}{\lambda ^{2}}}\sum _{k=1}^{n}\operatorname {Var} [X_{k}]={\frac {1}{\lambda ^{2}}}\sum _{k=1}^{n}{\text{E}}[X_{k}^{2}],}$ 

where S_k = X₁ + ... + X_k.

The convenience of this result is that we can bound the worst case deviation of a random walk at any point of time using its value at the end of time interval.

The following argument employs discrete martingales. As argued in the discussion of Doob's martingale inequality, the sequence ${\displaystyle S_{1},S_{2},\dots ,S_{n}}$  is a martingale. Define ${\displaystyle (Z_{i})_{i=0}^{n}}$  as follows. Let ${\displaystyle Z_{0}=0}$ , and

${\displaystyle Z_{i+1}=\left\{{\begin{array}{ll}S_{i+1}&{\text{ if }}\displaystyle \max _{1\leq j\leq i}|S_{j}|<\lambda \\Z_{i}&{\text{ otherwise}}\end{array}}\right.}$ 

for all ${\displaystyle i}$ . Then ${\displaystyle (Z_{i})_{i=0}^{n}}$  is also a martingale.

For any martingale ${\displaystyle M_{i}}$  with ${\displaystyle M_{0}=0}$ , we have that

${\displaystyle {\begin{aligned}\sum _{i=1}^{n}{\text{E}}[(M_{i}-M_{i-1})^{2}]&=\sum _{i=1}^{n}{\text{E}}[M_{i}^{2}-2M_{i}M_{i-1}+M_{i-1}^{2}]\\&=\sum _{i=1}^{n}{\text{E}}\left[M_{i}^{2}-2(M_{i-1}+M_{i}-M_{i-1})M_{i-1}+M_{i-1}^{2}\right]\\&=\sum _{i=1}^{n}{\text{E}}\left[M_{i}^{2}-M_{i-1}^{2}\right]-2{\text{E}}\left[M_{i-1}(M_{i}-M_{i-1})\right]\\&={\text{E}}[M_{n}^{2}]-{\text{E}}[M_{0}^{2}]={\text{E}}[M_{n}^{2}].\end{aligned}}}$ 

Applying this result to the martingale ${\displaystyle (S_{i})_{i=0}^{n}}$ , we have

${\displaystyle {\begin{aligned}{\text{Pr}}\left(\max _{1\leq i\leq n}|S_{i}|\geq \lambda \right)&={\text{Pr}}[|Z_{n}|\geq \lambda ]\\&\leq {\frac {1}{\lambda ^{2}}}{\text{E}}[Z_{n}^{2}]={\frac {1}{\lambda ^{2}}}\sum _{i=1}^{n}{\text{E}}[(Z_{i}-Z_{i-1})^{2}]\\&\leq {\frac {1}{\lambda ^{2}}}\sum _{i=1}^{n}{\text{E}}[(S_{i}-S_{i-1})^{2}]={\frac {1}{\lambda ^{2}}}{\text{E}}[S_{n}^{2}]={\frac {1}{\lambda ^{2}}}{\text{Var}}[S_{n}]\end{aligned}}}$ 

where the first inequality follows by Chebyshev's inequality.

This inequality was generalized by Hájek and Rényi in 1955.

• Chebyshev's inequality
• Etemadi's inequality
• Landau–Kolmogorov inequality
• Markov's inequality
• Bernstein inequalities (probability theory)

• Billingsley, Patrick (1995). Probability and Measure. New York: John Wiley & Sons, Inc. ISBN 0-471-00710-2. (Theorem 22.4)
• Feller, William (1968) [1950]. An Introduction to Probability Theory and its Applications, Vol 1 (Third ed.). New York: John Wiley & Sons, Inc. xviii+509. ISBN 0-471-25708-7.
• Kahane, Jean-Pierre (1985) [1968]. Some random series of functions (Second ed.). Cambridge: Cambridge University Press. p. 29-30.

This article incorporates material from Kolmogorov's inequality on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.