Complex two-mode quadratures - a generalized formalism for continuous-variable quantum optics

Quantum squeezing, a major resource of quantum information processing and quantum metrology, is best analyzed in terms of the field quadratures – the quantum optical analogs of position and momentum, which form the continuous-variable formalism of quantum light. Degenerate squeezing admits a very neat and simple description in terms of the single-mode quadrature operators, but the non-degenerate case requires a more complicated treatment involving correlations between the quadratures of the different modes.
We introduce a generalized set of complex quadrature operators that treats degenerate and non-degenerate squeezing on the same footing. We describe the mode-pairs (and photon-pairs) as a single entity, generalizing the concept of single-mode quadrature operators to two-mode fields of any bandwidth. These complex operators completely describe the SU(1,1) algebra of two-photon devices and directly relate to observable physical quantities, like power and visibility. We also discuss experimental schemes for measuring broadband two-mode quadratures using direct detection, and present a compact set of phase-dependent observables that completely and intuitively determine the two-mode squeezed state, and quantify the degree of entanglement and EPR inseparability between the modes.