LED module multi-physic approach

2016 22nd International Workshop on Thermal Investigations of ICs and Systems (THERMINIC) Pub Date : 2016-09-01 DOI:10.1109/THERMINIC.2016.7749050

T. Renaudin, J. Joly, B. Hamon, B. Tothe

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Abstract

Since the start of the Ledification of lighting systems, the multi-physic “optical, electrical, thermal” characterization of LED light sources is a critical task in Philips Lighting. Dedicated teams are responsible for determining multi-physic models and design-in rules of LED modules which will be later integrated in luminaires (lighting systems). Recent works have focus on generating more and more accurate LED Module mutli-physics models. These models have been used to predict and guaranty the performance, reliability and safety of the developed luminaires. In this paper, recent results regarding multi-physics models are exposed. The evolution of the test methods and equipment is discussed highlighting the major challenges in the definition of “boundary independent” LED modules models. In addition, an inter laboratory comparison has been conducted on T3ster equipment. The comparison outcomes have been gathered to provide a non-exhaustive, but useful identification of discrepancies root causes and sources of uncertainty. In this paper some guidelines will be provided to limit them.

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LED模组多物理场方法

自照明系统的Ledification开始以来，LED光源的多物理场“光学、电气、热”特性是飞利浦照明的一项关键任务。专门的团队负责确定LED模块的多物理模型和设计规则，这些模块随后将集成到灯具(照明系统)中。近年来的工作主要集中在生成越来越精确的LED模组多物理场模型上。这些模型已用于预测和保证所研制灯具的性能、可靠性和安全性。本文介绍了多物理场模型的最新研究成果。讨论了测试方法和设备的发展，强调了“边界独立”LED模块模型定义中的主要挑战。此外，还对T3ster设备进行了实验室间比较。收集比较结果是为了对差异的根本原因和不确定性的来源提供一个不详尽但有用的识别。本文将提供一些准则来限制它们。

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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2016 22nd International Workshop on Thermal Investigations of ICs and Systems (THERMINIC)

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