Abstract
Photons that are entangled or correlated in orbital angular momentum have been extensively used for remote sensing, object identification and imaging. It has recently been demonstrated that intensity fluctuations give rise to the formation of correlations in the orbital angular momentum components and angular positions of random light. Here we demonstrate that the spatial signatures and phase information of an object with rotational symmetries can be identified using classical orbital angular momentum correlations in random light. The Fourier components imprinted in the digital spiral spectrum of the object, as measured through intensity correlations, unveil its spatial and phase information. Sharing similarities with conventional compressive sensing protocols that exploit sparsity to reduce the number of measurements required to reconstruct a signal, our technique allows sensing of an object with fewer measurements than other schemes that use pixel-by-pixel imaging. One remarkable advantage of our technique is that it does not require the preparation of fragile quantum states of light and operates at both low- and high-light levels. In addition, our technique is robust against environmental noise, a fundamental feature of any realistic scheme for remote sensing.
Highlights
The orbital angular momentum (OAM) of light has attracted considerable attention in recent years
Our technique is robust against environmental noise, a fundamental feature of any realistic scheme for remote sensing
Fundamental tests of high-dimensional entangled systems have been performed through the OAM basis[2], the infinite OAM bases have been used to implement paradoxes in quantum mechanics[3] and relativistic effects have been explored in the azimuthal degree of freedom[4,5]
Summary
The orbital angular momentum (OAM) of light has attracted considerable attention in recent years. As identified by Allen et al.[1] in 1992, a beam of light with an azimuthal phase dependence of the form eÀicf carries OAM, where c is the mode index, which specifies the amount of OAM, and φ is the azimuthal angle. This interesting property of light has been explored in different contexts. Quantum OAM correlations[26] have been used to enhance the image contrast of phase objects[18]. Quantum correlations have been incorporated into digital spiral imaging to retrieve information of phase objects[21]. Field correlations in vectorial beams have been utilized for kinematic sensing[22]
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