recorded another result from Gelfand-Shilov of this form, now for the Fourier transform of the delta distribution applied to the “mass shell” of a quadratic form (here)

Also added as an example the observation that this result immediately implies that the singular support of the causal propagator in any dimension is the light cone.

]]>recorded a result from Gelfand-Shilov 66 on the Fourier transform of the principal value of powers of real quadratic forms (here).

Also added as an example the observartion that this result immediately implies that the singular support of the Feynman propagator in any dimension is the light cone.

Thanks to Igor Khavkine.

]]>I have made explicit the last step in the proof of $PV\left(\frac{1}{x}\right) = \frac{1}{x + i 0^+} + i \pi \delta$ (here).

Then I also complemented the Fourier expression of the Heaviside distribution with the converse statement (here) which is the “complex Schwinger parameterization”.

]]>Still lacking, though, the proof that

Ah, that follows of course immediately with the characterization of extension of distributions to the point.

I have also cross-linked now with *step function*, in fact I copied over the computation from there to *Cauchy principal value*: here

okay, I have added some content to *Cauchy principal value*.

(Still lacking, though, the proof that $PV(1/x) + c \delta(x)$ is the most general solution to $x f(x) = 1$.)

]]>I want to be adding some details to *Cauchy principal value*. What’s a good reference? Say for the proof that up to addition of a delta-distribution, $f(x) = pv\left( \frac{1}{x}\right)$ is the unique distributional solution to $x f = 1$?