Logarithmically concave function

In mathematics, a function $f:\mathbb {R} ^{n}\to \mathbb {R} ^{+}$ is logarithmically concave (or log-concave for short), if its natural logarithm $\ln(f(x))$ , is concave. This means that it must be:

f(\theta x+(1-\theta )y)\geq f(x)^{\theta }f(y)^{1-\theta }\qquad \theta \in [0,1]

Note that we allow here concave functions to take value -∞.

Examples of log-concave functions are the indicator functions of convex sets and the Gaussian function.

In parallel, a function is log-convex if its natural log is convex.

Properties

A log-concave function is also quasi-concave.

Every nonnegative concave function is log-concave, however the reverse does not necessarily hold. An example is the function

f(x)=e^{-x^{2}/2}

which is log-concave since

\log \,f(x)=-x^{2}/2

is a concave function of $x$ . But $f$ is not concave since the second derivative is positive for $|x|>1$ .

f''(x)=e^{-{\frac {x^{2}}{2}}}(x^{2}-1)\nleq 0

A twice differentiable function with convex ___domain is log-concave if and only if for all $x\in \operatorname {dom} f$ $f(x)>0$ and

f(x)\nabla ^{2}f(x)\preceq \nabla f(x)\nabla f(x)^{T}

, ^[1]

i.e. $f(x)\nabla ^{2}f(x)-\nabla f(x)\nabla f(x)^{T}$ is negative semi-definite. If $f:\mathbb {R} \to \mathbb {R} ^{+}$ , this condition simplifies to

f(x)f''(x)\leq (f'(x))^{2}

Operations preserving the log-concavity

Product (The product of log-concave functions is a log-concave function. Notice this is *not* true for the sum of log-concave functions.) If $f$ and $g$ are log-concave functions, $\log \,f(x)$ and $\log \,g(x)$ are concave by definition. Concavity is preserved under non-negative weighted sums, so

\log \,f(x)+\log \,g(x)=\log(f(x)g(x))

is concave, and therefore $f(x)g(x)$ is log-concave.

Integration in special cases:

If $f(x,y):{\mathcal {R}}^{n+m}\rightarrow {\mathcal {R}}$ is log-concave, then

g(x)=\int f(x,y)dy

is log-concave.

This implies that convolution is an operation preserving log-concavity since

h(x,y)=f(x-y)g(y)

is log-concave if f and g are log-concave, and therefore

(f*g)(x)=\int f(x-y)g(y)dy=\int h(x,y)dy

is log-concave.

References

^ Stephen Boyd and Lieven Vandenberghe, Convex Optimization (PDF) p.105

Barndorff-Nielsen, Ole (1978). Information and exponential families in statistical theory. Wiley Series in Probability and Mathematical Statistics. Chichester: John Wiley \& Sons, Ltd. pp. ix+238 pp. ISBN 0-471-99545-2. MR 0489333

Dharmadhikari, Sudhakar; Joag-Dev, Kumar (1988). Unimodality, convexity, and applications. Probability and Mathematical Statistics. Boston, MA: Academic Press, Inc. pp. xiv+278. ISBN 0-12-214690-5. {{cite book}}: Cite has empty unknown parameter: |1= (help) MR 0954608

Pfanzagl, Johann; with the assistance of R. Hamböker (1994). Parametric Statistical Theory. Walter de Gruyter. ISBN 3-11-01-3863-8. {{cite book}}: Cite has empty unknown parameter: |1= (help) MR 1291393

Pečarić, Josip E.; Proschan, Frank; Tong, Y. L. (1992). Convex functions, partial orderings, and statistical applications. Mathematics in Science and Engineering. Vol. 187. Boston, MA: Academic Press, Inc. pp. xiv+467 pp. ISBN 0-12-549250-2. {{cite book}}: Cite has empty unknown parameters: |1= and |2= (help) MR 1162312

Logarithmically concave function

Contents

Properties

Operations preserving the log-concavity

References

See also