Algebraic q-Integration and Fourier Theory on Quantum and Braided Spaces

Abstract

We introduce an algebraic theory of integration on quantum planes and other braided spaces. In the one dimensional case we obtain a novel picture of the Jackson q-integral as indefinite integration on the braided group of functions in one variable x. Here x is treated with braid statistics q rather than the usual bosonic or Grassmann ones. We show that the definite integral ∫ x can also be evaluated algebraically as multiples of the integral of a q-Gaussian, with x remaining as a bosonic scaling variable associated with the q-deformation. Further composing our algebraic integration with a representation then leads to ordinary numbers for the integral. We also use our integration to develop a full theory of q-Fourier transformation F. We use the braided addition x=x 1+1 x and braided-antipode S to define a convolution product, and prove a convolution theorem. We prove also that F2=S. We prove the analogous results on any braided group, including integration and Fourier transformation on quantum planes associated to general R-matrices, including q-Euclidean and q-Minkowski spaces.

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