Graphene-based double-mold hybrid integrated electronic control liquid crystal micro lens array chip

Abstract

The invention discloses a graphene-based double-mold hybrid integrated electronic control liquid crystal micro lens array chip which comprises an array light control framework, a first drive control signal input port and a second drive control signal input port. A first substrate, a first micro circular hole patterned graphene electrode, a first liquid crystal orientation layer, a first liquid crystal layer, a second liquid crystal orientation layer, a graphene ground electrode, a second substrate, a third liquid crystal orientation layer, a second liquid crystal layer, a fourth liquid crystal orientation layer, a second micro circular hole patterned graphene electrode and a third substrate are sequentially arranged between an upper layer and a lower layer of the array light control framework. The first micro circular hole patterned graphene electrode, the graphene ground electrode and the second micro circular hole patterned graphene electrode are fixed on the first substrate, the second substrate and the third substrate respectively. Each micro circular hole patterned graphene electrode comprises m*n micro circular holes and micro annular holes. The graphene-based double-mold hybrid integrated electronic control liquid crystal micro lens array chip is compact in structure, high in light beam conversion efficiency, easy to couple with conventional photoelectric machinery structures, and good in environment adaptability.

Description

technical field [0001] The invention belongs to the technical field of optical precision measurement and control, and more specifically relates to a graphene-based dual-mode hybrid integrated electronically controlled liquid crystal microlens array chip. Background technique [0002] So far, optical systems based on mechanical movement to match light-converging and light-diverging lenses have been able to effectively realize functions such as dynamic light wave conversion and adjustable construction of imaging and detection light fields. Its typical features are mainly manifested in the following aspects: (1) Modulating light beam parameters including focal length, point spread function and depth of focus; (2) increasing or reducing the illuminance distribution projected onto photosensitive arrays such as typical CCDs, CMOSs ​​or FPAs, etc. The range of irradiation application, environmental adaptability and radiation resolution of the array; (3) By modulating the incident l...

AI Technical Summary

Problems solved by technology

[0003] In recent years, the application fields of electro-mechanical optical systems with adjustable ability have been continuously expanded and extended, and the defects of the method of functionalized light wave conversion by coupling conventional light converging and light diverging lenses have become increasingly prominent, mainly reflected in The following aspects: (1) Because the optical lens with a fixed shape and profile presents non-adjustable beam transformation capabilities, only by adjusting the lens spacing to construct a specific beam shape and light energy transport form and perform modulation operations; (2) through The change of lens configuration by mechanical movement needs to be carried out in a specific order, the response is slow, time-consuming, and the inertia is large, and it needs to be matched with complex driving and control devices. Due to the intrinsic continuity of movement, it is impossible to perform arbitrary optical state cut-in or jump; (3) It is difficult Flexible access to the optical path or coupling with other optical optoelectronic mechanical devices; (4) It is impossible to perform functional beam conversion for photosensitive arrays such as CCD, CMOS or FPAs based on modern microelectronics and optoelectronics processes, and perform control of wavefront, wave spectrum, and wave Construction of optical-optical integrated imaging detection architecture based on vector, polarization, and energy flow, as well as chip-based transformation

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