Modal decomposition of optical fields as a concept has been in existence for many decades, yet despite its clear applications to laser beam analysis it has nevertheless remained a seldom used tool. With the commercialization of liquid crystal devices, digital holography as an enabling tool has become accessible to all, and with it modal decomposition has come of age. Here we outline the basic principles of modal decomposition of laser beams with digital holograms, and review recent results on the modal decomposition of arbitrary optical fields. We show how to use the information to infer the intensity, phase, wavefront, Poynting vector and orbital angular momentum density of the light. In particular, we show how to achieve optimal modal decomposition even in the absence of key information about the field, such as its scale and wavefront. We demonstrate the techniques on optical fields from fibers, diode-pumped solid-state lasers, and structured light by laser beam shaping.
Reference:
Forbes, A, Schulze, C, Ngcobo, S, Flamm, D, Naidoo, D, Dudley, A.L. and Duparre, M. 2013. Unraveling light with digital holograms. In: Proceedings of SPIE 8600, 86000U, Laser Resonators, Microresonators, and Beam Control XV, San Francisco, February 2013
Forbes, A., Schulze, C., Ngcobo, S., Flamm, D., Naidoo, D., Dudley, A. L., & Duparre, M. (2013). Unraveling light with digital holograms. SPIE Proceedings. http://hdl.handle.net/10204/7565
Forbes, A, C Schulze, Sandile Ngcobo, D Flamm, Darryl Naidoo, Angela L Dudley, and M Duparre. "Unraveling light with digital holograms." (2013): http://hdl.handle.net/10204/7565
Forbes A, Schulze C, Ngcobo S, Flamm D, Naidoo D, Dudley AL, et al, Unraveling light with digital holograms; SPIE Proceedings; 2013. http://hdl.handle.net/10204/7565 .
