Mathematical Foundations of Quantum Pricing Theory

Abstract

Let M be a von Neumann algebra and let (Nt)t∈[0,T] be an increasing family of abelian von Neumann subalgebras encoding a (classical) information flow. Fix a faithful normal state and a filtration of normal -preserving conditional expectations Et:M Nt satisfying the tower property. Using bounded functional-calculus cutoffs fn, we introduce a truncation-stable notion of localized (Nt,Et)-martingales for affiliated self-adjoint observables, and formulate a Local Informational Efficiency Principle requiring symmetrically discounted traded prices to be martingales in this sense. Assuming a pricing state and a compatible family of normal -preserving conditional expectations (Et), we define for bounded terminal payoffs X∈ MT the dynamic pricing operator \[ t(X):=Bt1/2\,Et\!(BT-1/2XBT-1/2)\,Bt1/2, \] where (Bt) is a strictly positive num\'eraire adapted to (Nt). We prove that (t) is normal, completely positive, Nt-bimodular, and time-consistent, and satisfies t( 1)=Bt (equivalently, t(X):=Bt-1/2t(X)Bt-1/2 is unital). In the commutative reduction it agrees with risk-neutral valuation by conditional expectation. Finally, we develop an L2(M,) prediction theory and introduce an operator-valued Fisher information relative to (Nt), obtaining a noncommutative Cram\'er--Rao lower bound for conditional mean-square prediction error; we compute the bound for compound Poisson lattice-jump models under Σαγα(eα x-1)=r.