A Spectral Fractional Hirota Bilinear Operator: Analysis and Application to a Time-Fractional KdV Equation

Abstract

We develop a fractional version of Hirota's bilinear calculus that is built directly from the spectral (Fourier-multiplier) fractional derivative on R. For 0<α 1 we define \[ Dαf· g := (Dαf)\,g - f\,(Dαg), \] equivalently through the two-variable extension D_1α-D_2α. In Fourier variables this is a bilinear multiplier with symbol (ik1)α-(ik2)α. For 0<α<1 we prove a Marchaud-type singular integral representation, and we use it to establish basic algebraic identities (bilinearity, skew-symmetry and Dαf· f=0), a Sobolev estimate Hs× Hs Hs-α for s>12, and convergence to the classical Hirota derivative as α 1-. As an application we derive a Hirota bilinear form for a spectral time-fractional KdV equation and construct explicit one- and two-soliton τ-functions. The fractional order changes the dispersion relation to ωα=-k3, while the two-soliton interaction coefficient agrees with the classical KdV value.