Progressive function

Template:More citations needed In mathematics, a progressive function ƒ ∈ L²(R) is a function whose Fourier transform is supported by positive frequencies only:^[1]

s u p p \hat{f} \subseteq ℝ_{+} .

It is called super regressive if and only if the time reversed function f(−t) is progressive, or equivalently, if

s u p p \hat{f} \subseteq ℝ_{-} .

The complex conjugate of a progressive function is regressive, and vice versa.

The space of progressive functions is sometimes denoted $H_{+}^{2} (R)$ , which is known as the Hardy space of the upper half-plane. This is because a progressive function has the Fourier inversion formula

f (t) = \int_{0}^{\infty} e^{2 π i s t} \hat{f} (s) d s

and hence extends to a holomorphic function on the upper half-plane ${t + i u : t, u \in R, u \geq 0}$

by the formula

f (t + i u) = \int_{0}^{\infty} e^{2 π i s (t + i u)} \hat{f} (s) d s = \int_{0}^{\infty} e^{2 π i s t} e^{- 2 π s u} \hat{f} (s) d s .

Conversely, every holomorphic function on the upper half-plane which is uniformly square-integrable on every horizontal line will arise in this manner.

Regressive functions are similarly associated with the Hardy space on the lower half-plane ${t + i u : t, u \in R, u \leq 0}$ .