Difference between revisions of "Parity"

Definition

The [math]n[/math]-variable parity function is the Boolean function [math]f:\{-1,1\}^n\to\{-1,1\}[/math] defined by [math]f(x)=x_1 \cdot x_2 \cdot \ldots \cdot x_n[/math]. In other words, [math]f(x)=1[/math] if and only if the number of ones in the vector [math]x\in\{-1,1\}^n[/math] is odd.

The name "parity" can also mean that the parity of only some [math]k[/math] of the [math]n[/math] bits is checked.

Properties

• Parity only depends on the number of ones and is therefore a symmetric Boolean function.
• The decision tree complexity of the parity function is [math]D(f)=n[/math].
• Over [math]\{-1,1\}[/math], the representation of the parity function is exactly the monomial [math]x_1 x_2 \ldots x_n[/math]. Thus all of its Fourier mass rests on the highest level.
• The n-variable parity function and its negation are the only Boolean functions for which all disjunctive normal forms have the maximal number of 2 ^n − 1 monomials of length n and all conjunctive normal forms have the maximal number of 2 ^n − 1 clauses of length n. ^[1]
• Parity is not in AC⁰: A constant-depth Boolean circuit must have super-polynomial size in order to represent the parity function. ^[2] In fact, a circuit of depth [math]d[/math] must have size [math]\exp n^{\Theta (\frac{1}{d-1})}[/math] in order to exactly compute parity. This is tight: there exists a circuit of this size which computes parity. ^{[3] [4]}
  • Parity cannot even be approximated in AC⁰: A circuit of depth [math]d[/math] and size [math]S[/math] can only have a correlation of [math]2^{-c_d n / (\log S)^{d-1} }[/math] with parity. ^[5]
• Parity over [math]n[/math] bits is odd when [math]n[/math] is odd, and even when [math]n[/math] is even.
• Parity has nearest neighbor complexity bounded by [math]NN(f) \geq n+1[/math]. It has the maximal Boolean nearest-neighbor complexity, [math]BNN(f) = 2^n[/math]. ^[6]

References