Quantum entanglement-based imaging promises significantly increased
resolution by extending the spatial separation of optical collection apertures
used in very-long-baseline interferometry for astronomy and geodesy. We report
a table-top entanglement-based interferometric imaging technique that utilizes
two entangled field modes serving as a phase reference between two apertures.
The spatial distribution of a simulated thermal light source is determined by
interfering light collected at each aperture with one of the entangled fields
and performing joint measurements. This experiment demonstrates the ability of
entanglement to implement interferometric imaging