TBan-I: Difference between revisions
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Consider the <math>M</math> energies <math>E_1, \dots, E_M</math> as independent and identically distributed (i.i.d.) random variables drawn from a distribution <math>p(E)</math>. It is useful to introduce the cumulative probability of finding an energy smaller than ''E'' | Consider the <math>M</math> energies <math>E_1, \dots, E_M</math> as independent and identically distributed (i.i.d.) random variables drawn from a distribution <math>p(E)</math>. It is useful to introduce the cumulative probability of finding an energy smaller than ''E'' | ||
<center> <math>P(E) = \int_{-\infty}^E dx \, p(x)</math> </center> | <center> <math>P(E) = \int_{-\infty}^E dx \, p(x)</math> </center> | ||
We define: | |||
<center> <math>E_{\min} = \min(E_1, \dots, E_M)</math> </center> | |||
Our goal is to compute the cumulative distribution: | |||
<center> <math>Q_M(E) \equiv \text{Prob}(E_{\min} > E)</math> </center> | |||
for large <math>M</math>. To achieve this, we rely on three key relations: | |||
Revision as of 16:31, 6 August 2025
Detour: Extreme Value Statistics
Consider the energies as independent and identically distributed (i.i.d.) random variables drawn from a distribution . It is useful to introduce the cumulative probability of finding an energy smaller than E
We define:
Our goal is to compute the cumulative distribution:
for large . To achieve this, we rely on three key relations: