McDiarmid's inequality

In

. McDiarmid's inequality applies to functions that satisfy a bounded differences property, meaning that replacing a single argument to the function while leaving all other arguments unchanged cannot cause too large of a change in the value of the function.

Statement

A function ${\displaystyle f:{\mathcal {X}}_{1}\times {\mathcal {X}}_{2}\times \cdots \times {\mathcal {X}}_{n}\rightarrow \mathbb {R} }$ satisfies the bounded differences property if substituting the value of the ${\displaystyle i}$th coordinate ${\displaystyle x_{i}}$ changes the value of ${\displaystyle f}$ by at most ${\displaystyle c_{i}}$. More formally, if there are constants ${\displaystyle c_{1},c_{2},\dots ,c_{n}}$ such that for all ${\displaystyle i\in [n]}$, and all ${\displaystyle x_{1}\in {\mathcal {X}}_{1},\,x_{2}\in {\mathcal {X}}_{2},\,\ldots ,\,x_{n}\in {\mathcal {X}}_{n}}$,

${\displaystyle \sup _{x_{i}'\in {\mathcal {X}}_{i}}\left|f(x_{1},\dots ,x_{i-1},x_{i},x_{i+1},\ldots ,x_{n})-f(x_{1},\dots ,x_{i-1},x_{i}',x_{i+1},\ldots ,x_{n})\right|\leq c_{i}.}$

Extensions

Unbalanced distributions

A stronger bound may be given when the arguments to the function are sampled from unbalanced distributions, such that resampling a single argument rarely causes a large change to the function value.

This may be used to characterize, for example, the value of a function on

, since in a sparse random graph, it is much more likely for any particular edge to be missing than to be present.

Differences bounded with high probability

McDiarmid's inequality may be extended to the case where the function being analyzed does not strictly satisfy the bounded differences property, but large differences remain very rare.

There exist stronger refinements to this analysis in some distribution-dependent scenarios,^[6] such as those that arise in learning theory.

Sub-Gaussian and sub-exponential norms

Let the ${\displaystyle k}$th centered conditional version of a function ${\displaystyle f}$ be

${\displaystyle f_{k}(X)(x):=f(x_{1},\ldots ,x_{k-1},X_{k},x_{k+1},\ldots ,x_{n})-\mathbb {E} _{X'_{k}}f(x_{1},\ldots ,x_{k-1},X'_{k},x_{k+1},\ldots ,x_{n}),}$

so that ${\displaystyle f_{k}(X)}$ is a random variable depending on random values of ${\displaystyle x_{1},\ldots ,x_{k-1},x_{k+1},\ldots ,x_{n}}$.

Bennett and Bernstein forms

Refinements to McDiarmid's inequality in the style of Bennett's inequality and Bernstein inequalities are made possible by defining a variance term for each function argument. Let

${\displaystyle {\begin{aligned}B&:=\max _{k\in [n]}\sup _{x_{1},\dots ,x_{k-1},x_{k+1},\dots ,x_{n}}\left|f(x_{1},\dots ,x_{k-1},X_{k},x_{k+1},\dots ,x_{n})-\mathbb {E} _{X_{k}}f(x_{1},\dots ,x_{k-1},X_{k},x_{k+1},\dots ,x_{n})\right|,\\V_{k}&:=\sup _{x_{1},\dots ,x_{k-1},x_{k+1},\dots ,x_{n}}\mathbb {E} _{X_{k}}\left(f(x_{1},\dots ,x_{k-1},X_{k},x_{k+1},\dots ,x_{n})-\mathbb {E} _{X_{k}}f(x_{1},\dots ,x_{k-1},X_{k},x_{k+1},\dots ,x_{n})\right)^{2},\\{\tilde {\sigma }}^{2}&:=\sum _{k=1}^{n}V_{k}.\end{aligned}}}$

Proof

The following proof of McDiarmid's inequality

). An alternate argument avoiding the use of martingales also exists, taking advantage of the independence of the function arguments to provide a Chernoff-bound-like argument.^[4]

For better readability, we will introduce a notational shorthand: ${\displaystyle z_{i\rightharpoondown j}}$ will denote ${\displaystyle z_{i},\dots ,z_{j}}$ for any ${\displaystyle z\in {\mathcal {X}}^{n}}$ and integers ${\displaystyle 1\leq i\leq j\leq n}$, so that, for example,

${\displaystyle f(X_{1\rightharpoondown (i-1)},y,x_{(i+1)\rightharpoondown n}):=f(X_{1},\ldots ,X_{i-1},y,x_{i+1},\ldots ,x_{n}).}$

Pick any ${\displaystyle x_{1}',x_{2}',\ldots ,x_{n}'}$. Then, for any ${\displaystyle x_{1},x_{2},\ldots ,x_{n}}$, by triangle inequality,

${\displaystyle {\begin{aligned}&|f(x_{1\rightharpoondown n})-f(x'_{1\rightharpoondown n})|\\[6pt]\leq {}&|f(x_{1\rightharpoondown \,n})-f(x'_{1\rightharpoondown (n-1)},x_{n})|+c_{n}\\\leq {}&|f(x_{1\rightharpoondown n})-f(x'_{1\rightharpoondown (n-2)},x_{(n-1)\rightharpoondown n})|+c_{n-1}+c_{n}\\\leq {}&\ldots \\\leq {}&\sum _{i=1}^{n}c_{i},\end{aligned}}}$

and thus ${\displaystyle f}$ is bounded.

Since ${\displaystyle f}$ is bounded, define the Doob martingale ${\displaystyle \{Z_{i}\}}$ (each ${\displaystyle Z_{i}}$ being a random variable depending on the random values of ${\displaystyle X_{1},\ldots ,X_{i}}$) as

${\displaystyle Z_{i}:=\mathbb {E} [f(X_{1\rightharpoondown n})\mid X_{1\rightharpoondown i}]}$

for all ${\displaystyle i\geq 1}$ and ${\displaystyle Z_{0}:=\mathbb {E} [f(X_{1\rightharpoondown n})]}$, so that ${\displaystyle Z_{n}=f(X_{1\rightharpoondown n})}$.

Now define the random variables for each ${\displaystyle i}$

${\displaystyle {\begin{aligned}U_{i}&:=\sup _{x\in {\mathcal {X}}_{i}}\mathbb {E} [f(X_{1\rightharpoondown (i-1)},x,X_{(i+1)\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)},X_{i}=x]-\mathbb {[} f(X_{1\rightharpoondown (i-1)},X_{i\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}],\\L_{i}&:=\inf _{x\in {\mathcal {X}}_{i}}\mathbb {E} [f(X_{1\rightharpoondown (i-1)},x,X_{(i+1)\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)},X_{i}=x]-\mathbb {[} f(X_{1\rightharpoondown (i-1)},X_{i\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}].\\\end{aligned}}}$

Since ${\displaystyle X_{i},\ldots ,X_{n}}$ are independent of each other, conditioning on ${\displaystyle X_{i}=x}$ does not affect the probabilities of the other variables, so these are equal to the expressions

${\displaystyle {\begin{aligned}U_{i}&=\sup _{x\in {\mathcal {X}}_{i}}\mathbb {E} [f(X_{1\rightharpoondown (i-1)},x,X_{(i+1)\rightharpoondown n})-f(X_{1\rightharpoondown (i-1)},X_{i\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}],\\L_{i}&=\inf _{x\in {\mathcal {X}}_{i}}\mathbb {E} [f(X_{1\rightharpoondown (i-1)},x,X_{(i+1)\rightharpoondown n})-f(X_{1\rightharpoondown (i-1)},X_{i\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}].\\\end{aligned}}}$

Note that ${\displaystyle L_{i}\leq Z_{i}-Z_{i-1}\leq U_{i}}$. In addition,

${\displaystyle {\begin{aligned}U_{i}-L_{i}&=\sup _{u\in {\mathcal {X}}_{i},\ell \in {\mathcal {X}}_{i}}\mathbb {E} [f(X_{1\rightharpoondown (i-1)},u,X_{(i+1)\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}]-\mathbb {E} [f(X_{1\rightharpoondown (i-1)},\ell ,X_{(i+1)\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}]\\[6pt]&=\sup _{u\in {\mathcal {X}}_{i},\ell \in {\mathcal {X}}_{i}}\mathbb {E} [f(X_{1\rightharpoondown (i-1)},u,X_{(i+1)\rightharpoondown n})-f(X_{1\rightharpoondown (i-1)},l,X_{(i+1)\rightharpoondown n})\mid X_{1\rightharpoondown (i-1)}]\\&\leq \sup _{x_{u}\in {\mathcal {X}}_{i},x_{l}\in {\mathcal {X}}_{i}}\mathbb {E} [c_{i}\mid X_{1\rightharpoondown (i-1)}]\\[6pt]&\leq c_{i}\end{aligned}}}$

Then, applying the general form of Azuma's inequality to ${\displaystyle \left\{Z_{i}\right\}}$, we have

${\displaystyle {\text{P}}(f(X_{1},\ldots ,X_{n})-\mathbb {E} [f(X_{1},\ldots ,X_{n})]\geq \varepsilon )=\operatorname {P} (Z_{n}-Z_{0}\geq \varepsilon )\leq \exp \left(-{\frac {2\varepsilon ^{2}}{\sum _{i=1}^{n}c_{i}^{2}}}\right).}$

The one-sided bound in the other direction is obtained by applying Azuma's inequality to ${\displaystyle \left\{-Z_{i}\right\}}$ and the two-sided bound follows from a union bound. ${\displaystyle \square }$

See also

References