Abstract
A discrete optical system can broaden the spatial distribution of the input light through optical coupling in array waveguides, just like diffraction in continuous media. Here, we theoretically demonstrate several kinds of control methods of optical field propagation in a discrete optical system, which is composed of an Airy fiber with two perpendicular arrayed cores. A brief transform mechanism between Gaussian and Airy beam propagation in such a fiber is presented. The wavefront of the output beam from the Airy fiber is actually dependent on the phased arrayed modulation of coupling array cores. Except the optical wavelength changing, we propose two new methods, including fiber length and bending-induced refractive-index changing, to accomplish that modulation. The calculation results show that these new methods are very effective for the Airy phase modulation. By combining these methods and controlling the corresponding parameters, the Gaussian beam, the one-dimension Airy beam, and the two-dimension Airy beam can be obtained by one same Airy fiber. These methods are also generally applicable to the other discrete optical system and can be extended to generate any other types of optical beams, such as Bessel beams and Mathieu beams.
Highlights
The Airy beam (AB) have propagation-invariant intensity profile and exhibit ‘self-healing’ features[1,2,3]
We focus on studying the transform mechanism between Gaussian and Airy beam propagation in such a fiber
As we described in the previous section, a discrete optical system is designed by using an Airy fiber with two perpendicular arrayed cores to implement transform between Gaussian beam and Airy beam through Airy amplitude and phased array modulation
Summary
The Airy beam (AB) have propagation-invariant intensity profile and exhibit ‘self-healing’ features[1,2,3] Such a beam has an ability to remain transverse accelerating during propagation[4], which moves on a parabolic trajectory very much like a body under the action of gravity. In our previous work[16, 17], a one/two-dimensional (1D/2D) Airy-like beam technique was reported based on array waveguides instead of a cubic phase plate. Such an Airy fiber has a small size, easy handling, stable and strong anti-jamming capability. We further demonstrate the consistency and validity of these methods and reveal that the propagation properties of Airy fiber are strongly related to the phased array modulation based on waveguide coupling
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