Polymer optical waveguide lens with large optical coupling tolerance by segmented waveguide structure

Matsushima, Naoki

doi:10.7567/jjap.54.052501

Jpn. J. Appl. Phys.

2015

DOI: 10.7567/jjap.54.052501

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Polymer optical waveguide lens with large optical coupling tolerance by segmented waveguide structure

Naoki Matsushima¹

Abstract: A polymer optical waveguide lens with large optical coupling tolerance has been developed. An extension in the tolerance for laser diode (LD) positional misalignment has been obtained by using segmented optical waveguides on the edge of the optical waveguide that can control the beam spot size of the propagated optical beam. The proposed structure is calculated based on an extension of about 40% with a 0.5 dB misalignment tolerance. The effect of the tolerance extension is also obtained when measuring the opti… Show more

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Cited by 2 publications

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“…Photonic lattices consisting of evanescently coupled waveguide arrays could be defined as appropriate configurations, in which the optical modes can be engineered along the transverse direction. Particularly, the periodically segmented waveguide is investigated both for a single waveguide [24,25] and in the array [26], which is used for image reconstruction [27], optical lens [28], and generating controllable loss [29]. Because of the analogy of the Schrödinger equation for quantum wave functions and the paraxial Helmholtz equation for classical electric fields, the temporal evolution of a quantum system is therefore equivalent to spatial propagation of guided light waves in waveguides [30,31].…”

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confidence: 99%

Engineering of Zeno Dynamics in Integrated Photonics

Liu

Ziegler

et al. 2023

Phys. Rev. Lett.

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Frequent observations to a quantum system modify its coherent evolution through the Zeno effect and Zeno dynamics. Generally, the measurement process destroys the evolution environment of the monitored system, making repeated observations remain a challenge. Here, using the quantum analogy experiments, we realize and engineer the Zeno effect and Zeno dynamics in optical waveguide arrays, where the optical modes correspond to distinct quantum states, and the temporal evolution is mapped into the spatial propagation. We propose a new, extensible experimental strategy for realizing an optical analog of stroboscopic measurements, which are performed by the build-in, on-demand segmented waveguide portions. The weak-to-strong stroboscopic measurements are realized, where the monitored system undergoes a transition from free evolution to optical Zeno freezing. Setting the measurements in the strong regime, the optical Zeno effect and optical Zeno dynamics are successfully generated, and their relationship is demonstrated in optics. We then propose a novel quantum Zeno slicing approach, which allows us to dynamically engineer the Hilbert space of the monitored system. This generic approach is verified by generating a series of Zeno subspaces with different measurement projectors, based on the quantum-optical analogy. The complexity of light dynamics is largely increased, providing full control of the propagation via steering Zeno dynamics. Our results pave the way for manipulation of quantum states by harnessing Zeno dynamics in integrated photonics.

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confidence: 99%

Engineering of Zeno Dynamics in Integrated Photonics

Liu

Ziegler

et al. 2023

Phys. Rev. Lett.

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Segmented waveguide arrays: deriving discrete diffraction relations in a square lattice photonic crystal

et al. 2017

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Segmented strip-loaded waveguide arrays are investigated within a rigorous square lattice photonic crystal model. We derive a full multiband discrete diffraction approach for near-axial injection in the direction of a lattice vector. We obtain an effective waveguide array picture, with quasi-linear dependence on the segmentation ratio in a simplified single-band scheme. Our results are validated by beam deviation experiments. Such a diffraction framework allows for efficient shaping of the phase map in waveguide arrays and enriches the engineering toolkit of photonic crystals with the in-plane free propagation structures of discrete photonics.

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Polymer optical waveguide lens with large optical coupling tolerance by segmented waveguide structure

Cited by 2 publications

References 25 publications

Engineering of Zeno Dynamics in Integrated Photonics

Engineering of Zeno Dynamics in Integrated Photonics

Segmented waveguide arrays: deriving discrete diffraction relations in a square lattice photonic crystal

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