Quantum-limited localization and resolution in three dimensions

As a method to extract information from optical systems, imaging can be viewed as a parameter estimation problem. The fundamental precision in locating one emitter or estimating the separation between two incoherent emitters is bounded below by the multiparameter quantum Cramer-Rao bound (QCRB). Multiparameter QCRB gives an intrinsic bound in parameter estimation. We determine the ultimate potential of quantum-limited imaging for improving the resolution of a far-field, diffraction-limited optical field within the paraxial approximation. We show that the quantum Fisher information matrix (QFIm) in about one emitter's position is independent on its true value. We calculate the QFIm of two unequal-brightness emitters' relative positions and intensities; the results show that only when the relative intensity and centroids of two-point sources, including longitudinal and transverse directions, are known exactly, the separation in different directions can be estimated simultaneously with finite precision. Our results give the upper bounds on certain far-field imaging technology and will find wide use in applications from microscopy to astrometry. (C) 2021 Chinese Laser Press

Automated summary

This study investigates the parameter estimation problem based on quantum-limited imaging, providing intrinsic bounds and matrices based on quantum Cramer-Rao bound and quantum Fisher information matrix. These results have wide application value in certain far-field imaging technologies.