Models of reduced-noise, probabilistic linear amplifiers
arXiv:1603.03150 · doi:10.1103/PhysRevA.93.052310
Abstract
We construct an amplifier that interpolates between a nondeterministic, immaculate linear amplifier and a deterministic, ideal linear amplifier and beyond to nonideal linear amplifiers. The construction involves cascading an immaculate linear amplifier that has amplitude gain $g_1$ with a (possibly) nonideal linear amplifier that has gain $g_2$. With respect to normally ordered moments, the device has output noise $μ^2(G^2-1)$ where $G=g_1 g_2$ is the overall amplitude gain and $μ^2$ is a noise parameter. When $μ^2\ge1$, our devices realize ideal ($μ^2=1$) and nonideal ($μ^2>1$) linear amplifiers. When $0\leμ^2<1$, these devices work effectively only over a restricted region of phase space and with some subunity success probability $p_{\checkmark}$. We investigate the performance of our $μ^2$-amplifiers in terms of a gain-corrected probability-fidelity product and the ratio of input to output signal-to-noise ratios corrected for success probability.
14 pages, 10 figures