In the following exercises, we will use the notation from extreme value statistics as introduced in the course.

Exercise 1: The Gumbel Distribution

Let's go back to the end of Lecture 1. In the Gaussian case, expand ${\displaystyle A(E)}$ around ${\displaystyle a_{M}}$:

${\displaystyle Q_{M}(E)\sim \exp \left(-MP(E)\right)\sim \exp \left(-Me^{A(a_{M})+A'(a_{M})\cdot (E-a_{M})}\right)}$

Show that by setting

${\displaystyle a_{M}=E_{\min }^{\text{typ}}=-\sigma {\sqrt {2\log M}}+\ldots \quad {\text{and}}\quad b_{M}={\frac {1}{A'(a_{M})}}={\frac {\sigma }{\sqrt {2\log M}}}}$

you find

${\displaystyle \exp(A(a_{M}))={\frac {1}{M}}\qquad {\text{and}}\qquad Q_{M}(E)\equiv {\text{Prob}}(E_{\min }>E)\sim \exp \!\!\left[-\exp \!\!\left({\frac {E-a_{M}}{b_{M}}}\right)\right]}$

Therefore, the variable ${\displaystyle z=(E-a_{M})/b_{M}}$ is distributed according to an M-independent distribution.

It is possible to generalize this result and classify the scaling forms into the Gumbel universality class:

• Characteristics:
  • Applies when the tails of ${\displaystyle p(E)}$ decay faster than any power law.
  • Examples: the Gaussian case discussed here or exponential distributions ${\displaystyle p(E)=\exp(E)\quad {\text{with}}\quad E\in (-\infty ,0)}$.

• Scaling Form: ${\displaystyle \exp(z)\,\exp(-e^{z})}$

Exercise 2: The Weakest Link and the Weibull Distribution

Consider a chain of length ${\displaystyle L}$ subjected to a tensile force ${\displaystyle F}$. Define ${\displaystyle F_{c}}$ as the force required to break the chain. The goal of this exercise is to determine how ${\displaystyle F_{c}}$ depends on ${\displaystyle L}$ and to characterize its sample-to-sample fluctuations. Throughout the exercise, you work in the limit of large ${\displaystyle L}$.

Let ${\displaystyle x_{1},x_{2},\dots ,x_{L}}$ denote the strengths of the individual links. Assume that these are positive, identically distributed, and independent random variables. Consider the Gamma distribution with shape parameter ${\displaystyle \alpha >0}$ and ${\displaystyle \Gamma (\alpha )}$ the Gamma function:

${\displaystyle p(x)={\frac {x^{\alpha -1}}{\Gamma (\alpha )}}e^{-x}}$

Exercise 3: number of states above the minimum

Definition of ${\displaystyle n(x)}$:Given a realization of the random energies ${\displaystyle {E_{1},E_{2},\ldots ,E_{M}}}$, define

${\displaystyle n(x)=\#\{i\mid E_{\min }<E_{i}<E_{\min }+x\}}$

that is, the number of random variables lying above the minimum ${\displaystyle E_{\min }}$ but less than ${\displaystyle E_{\min }+x}$. This is itself a random variable. We are interested in its mean value:

${\displaystyle {\overline {n(x)}}=\sum _{k=0}^{M-1}k\,{\text{Prob}}[n(x)=k]}$

The Final goal is to show that, for large M (when the extremes are described by the Gumbel distribution), you have:

${\displaystyle {\overline {n(x)}}=e^{x/b_{M}}-1}$

Step 1: Exact manipulations: You start from the exact expression for the probability of ${\displaystyle k}$ states in the interval:

${\displaystyle {\text{Prob}}[n(x)=k]=M{\binom {M-1}{k}}\int _{-\infty }^{\infty }dE\;p(E)\,[P(E+x)-P(E)]^{k}\,[1-P(E+x)]^{M-k-1}}$

To compute ${\displaystyle {\overline {n(x)}}}$, you must sum over ${\displaystyle k}$. Use the identity

${\displaystyle \sum _{k=0}^{M-1}k{\binom {M-1}{k}}(A-B)^{k}B^{M-1-k}=(A-B){\frac {d}{dA}}\sum _{k=0}^{M-1}{\binom {M-1}{k}}(A-B)^{k}B^{M-1-k}=(M-1)(A-B)A^{M-2}}$

to arrive at the form:

${\displaystyle {\overline {n(x)}}=M(M-1)\int _{-\infty }^{\infty }dE\;p(E)\left[P(E+x)-P(E)\right](1-P(E))^{M-2}=M\int _{-\infty }^{\infty }dE\;\left[P(E+x)-P(E)\right]{\frac {dQ_{M-1}(E)}{dE}}}$

where ${\displaystyle Q_{M-1}(E)=[1-P(E)]^{M-1}}$.

Step 2: the Gumbel limit So far, no approximations have been made. To proceed, we use ${\displaystyle Q_{M-1}(E)\approx Q_{M}(E)}$ and its asymptotics Gumbel form:

${\displaystyle {\frac {dQ_{M-1}(E)}{dE}}\,dE\;\sim \;\exp \!\!\left({\frac {E-a_{M}}{b_{M}}}\right)\exp \!\!\left[-\exp \!\!\left({\frac {E-a_{M}}{b_{M}}}\right)\right]{\frac {dE}{b_{M}}}=e^{z}e^{-e^{z}}dz}$

where ${\displaystyle z=(E-a_{M})/b_{M}}$.

The main contribution to the integral comes from the region near ${\displaystyle E\approx a_{M}}$, where ${\displaystyle P(E)\approx e^{(E-a_{M})/b_{M}}/M}$.

Compute the integral and verify that you obtain:

${\displaystyle {\overline {n(x)}}={\bigl (}e^{x/b_{M}}-1{\bigr )}\int _{-\infty }^{\infty }dz\,e^{2z-e^{z}}=e^{x/b_{M}}-1}$