In mathematics, the BrascampâÂÂLieb inequality is either of two inequalities. The first is a result in geometry concerning integrable functions on n-dimensional Euclidean space . It generalizes the LoomisâÂÂWhitney inequality and Hölder's inequality. The second is a result of probability theory which gives a concentration inequality for log-concave probability distributions. Both are named after Herm Jan Brascamp and Elliott H. Lieb.
Fix natural numbers m and n. For 1 ⤠i ⤠m, let n<sub>i</sub> â N and let c<sub>i</sub> > 0 so that
Choose non-negative, integrable functions
and surjective linear maps
Then the following inequality holds:
where D is given by
Another way to state this is that the constant D is what one would obtain by restricting attention to the case in which each is a centered Gaussian function, namely .
Consider a probability density function . This probability density function is said to be a log-concave measure if the function is convex. Such probability density functions have tails which decay exponentially fast, so most of the probability mass resides in a small region around the mode of . The BrascampâÂÂLieb inequality gives another characterization of the compactness of by bounding the mean of any statistic .
Formally, let be any derivable function. The BrascampâÂÂLieb inequality reads:
where H is the Hessian and is the Nabla symbol.
The inequality is generalized in 2008 to account for both continuous and discrete cases, and for all linear maps, with precise estimates on the constant.
Definition: the Brascamp-Lieb datum (BL datum)
For any with , define
Now define the Brascamp-Lieb constant for the BL datum:
Setup:
With this setup, we have (Theorem 2.4, Theorem 3.12 )
Note that the constant is not always tight.
Given BL datum , the conditions for are
Thus, the subset of that satisfies the above two conditions is a closed convex polytope defined by linear inequalities. This is the BL polytope.
Note that while there are infinitely many possible choices of subspace of , there are only finitely many possible equations of , so the subset is a closed convex polytope.
Similarly we can define the BL polytope for the discrete case.
The case of the Brascamp–Lieb inequality in which all the n<sub>i</sub> are equal to 1 was proved earlier than the general case. In 1989, Keith Ball introduced a "geometric form" of this inequality. Suppose that are unit vectors in and are positive numbers satisfying
for all , and that are positive measurable functions on . Then
Thus, when the vectors resolve the inner product the inequality has a particularly simple form: the constant is equal to 1 and the extremal Gaussian densities are identical. Ball used this inequality to estimate volume ratios and isoperimetric quotients for convex sets in and.
There is also a geometric version of the more general inequality in which the maps are orthogonal projections and
where is the identity operator on .
Take n<sub>i</sub> = n, B<sub>i</sub> = id, the identity map on , replacing f<sub>i</sub> by f, and let c<sub>i</sub> = 1 / p<sub>i</sub> for 1 ⤠i ⤠m. Then
and the log-concavity of the determinant of a positive definite matrix implies that D = 1. This yields Hölder's inequality in :
The BrascampâÂÂLieb inequality is an extension of the Poincaré inequality which only concerns Gaussian probability distributions.
The BrascampâÂÂLieb inequality is also related to the CramérâÂÂRao bound. While BrascampâÂÂLieb is an upper-bound, the CramérâÂÂRao bound lower-bounds the variance of . The CramérâÂÂRao bound states
which is very similar to the BrascampâÂÂLieb inequality in the alternative form shown above.