High Brightness Illumination Based on Laser Light Diffusion With Mie Scattering

ASME 2022 International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems Pub Date : 2022-10-25 DOI:10.1115/ipack2022-97220

Mohammad Azarifar, Ceren Cengiz, Kerem Ocaksönmez, Asim Onal, S. Nizamoglu, M. Arik

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Abstract

Limited luminous flux per wafer area of light emitting diodes (LEDs) for high power solid state illumination causes some packaging real estate issues. This problem can be tackled with laser diodes (LDs). At high current densities, LDs offer higher efficiency, however with very low etendue and divergent angle. This significantly increases the complexity of color conversion for white light generation. Concentrated light can carbonize the color conversion unit and have high speckle contrast. These problems can be addressed by efficient diffusion of the laser beam and this paper is aimed to introduce the first laser diffusion system based on TiO2 Mie particles. Based on a series of ray tracing simulations, an idealized cost-effective system is modeled and results showed an almost lossless diffusion with a guiding system based on reflection resulting in an almost uniform irradiance level with only 17% power loss. Furthermore, offered design can reduce the challenges for the compact packaging of white LDs by eliminating the heat sink for color conversion coating and enabling a safe light intensity for utilizing quantum dots for color engineering.

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基于米氏散射激光扩散的高亮度照明

用于高功率固态照明的发光二极管(led)每晶圆面积的光通量有限，导致一些封装空间问题。这个问题可以用激光二极管(ld)来解决。在高电流密度下，lcd具有更高的效率，但其端程和发散角非常低。这大大增加了白光产生的颜色转换的复杂性。聚光可以碳化颜色转换单元，具有很高的斑点对比度。这些问题可以通过激光光束的有效扩散来解决，本文旨在介绍第一个基于TiO2 Mie粒子的激光扩散系统。基于一系列的光线追踪模拟，对一个理想的经济高效的系统进行了建模，结果表明，在基于反射的引导系统下，几乎无损失的扩散产生了几乎均匀的辐照水平，只有17%的功率损失。此外，所提供的设计可以通过消除用于颜色转换涂层的散热器，并为利用量子点进行颜色工程提供安全的光强，从而减少白色ld紧凑封装的挑战。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ASME 2022 International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems

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