Statistics of a multi-factor function from its Fourier transform
Matthew A. Herman, Stephen Doro
TLDR
A new theorem enables deriving multi-factor function statistics from its Fourier transform, revealing hidden relationships via index annihilation.
Key contributions
- Derives population statistics for multi-factor functions using only their Fourier transform.
- Presents the m-Coefficient/Index Annihilation Theorem for calculating function moments.
- Identifies that Fourier coefficient indices in moment terms sum to zero, filtering relevant terms.
- Reveals deeper relationships between variables and serves as an analytical/design tool.
Why it matters
This paper offers a powerful method to analyze multi-factor functions by deriving their statistics directly from the Fourier domain. The Annihilation Theorem provides a unique filtering mechanism, simplifying analysis and revealing fundamental variable relationships. This is valuable for theoretical insights and practical applications.
Original Abstract
For a phenomenon $\boldsymbol{f}$ that is a function of~$n$ factors, defined on a finite abelian group $G$, we derive its population statistics solely from its Fourier transform $\hat{\boldsymbol{f}}$. Our main result is an \emph{$m$-Coefficient/Index Annihilation Theorem}: the $m$th moment of $\boldsymbol{f}$ becomes a series of terms, each with precisely $m$ Fourier coefficients --- and surprisingly, the coefficient \emph{indices} in each term sum to zero under group addition. This condition acts like a filter, limiting which terms appear in the Fourier domain, and can reveal deeper relationships between the variables driving $\boldsymbol{f}$. These techniques can also be used as an analytical/design tool, or as a feasibility constraint in search algorithms. For functions defined on $\mathbb{Z}_2^n$, we show how the skew, kurtosis, etc. of a binomial distribution can be derived from the Fourier domain. Several other examples are presented.
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