Substantial advances in quantitative infrared vision

定量红外视觉的重大进展

• 批准号: 327699-2006
• 负责人: Bendada, Abdelhakim
• 金额: $ 2.29万
• 依托单位: Université Laval
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2006
• 资助国家: 加拿大
• 起止时间: 2006-01-01 至 2007-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=339311
• 关键词: Substantial; advances; quantitative; infrared; vision

Infrared (IR) thermography is an ideal tool for the nondestructive testing of materials. Basically, the observation is carried out either in a passive or active mode. The passive mode consists in using the natural heat developed within the material and observing the temperature distribution as it appears. In the active mode, an external heat source is used to create a thermal perturbation within the material under investigation. Subsequently, an IR imager is used to analyze the thermal wave propagation whose anomalies reveal hidden flaws. An important part of the success of the method is based on how the thermal perturbation (active mode) is transmitted to the material. Another factor that is of paramount importance is image processing (active and passive modes) since it allows the interpretation of the observed phenomena. So far, conventional thermography techniques have encountered several limitations at both the detection and interpretation stages. The proposed research program focuses on investigating new ways of solving the key problems. Our short term objectives will cover the following directions: (1) Investigation of optimal active thermography experiments: the objective is to analyze via theory and experiments the effect of different spatially, and spectrally varying heating modes; the aim is to enhance the detectability of the flaws; (2) Advanced processing methods: methods for solving inverse problems through the state of the art in data compression algorithms such as thermographic signal reconstruction (TSR) or principle component analysis (PCA); planned innovations are for instance into neural networks (NN); (3) Thermophysics for active thermography: the goal is to reliably measure thermal properties of the vast range of new materials subjected to thermal nondestructive tests; thermal properties are required to feed thermal simulation and flaw characterization codes. (4) Design of low-cost inspection systems: the objective is to design low-cost IR thermography setups that might be used by small and medium-size Canadian companies which cannot afford high-end equipment. Powerful built-in processing combined with the new technology of "tiny" uncooled IR cameras will lead to the development of such systems.

红外热成像技术是材料无损检测的理想工具。基本上，观察以被动或主动模式进行。被动模式包括使用材料内产生的自然热并观察温度分布。在主动模式下，外部热源用于在被研究的材料内产生热扰动。随后，红外成像仪被用来分析热波传播的异常揭示隐藏的缺陷。该方法成功的一个重要部分是基于热扰动（主动模式）如何传递到材料。另一个至关重要的因素是图像处理（主动和被动模式），因为它可以解释观察到的现象。到目前为止，传统的热成像技术在探测和解释阶段都遇到了一些限制。拟议的研究计划侧重于研究解决关键问题的新方法。我们的短期目标将包括以下几个方面：（1）最佳主动热成像实验的研究：目标是通过理论和实验分析不同空间和光谱变化加热模式的效果;目的是提高缺陷的可检测性;（2）先进的处理方法：通过数据压缩算法中的现有技术解决逆问题的方法，例如热像信号重构（TSR）或主成分分析（PCA）;计划的创新例如是神经网络（NN）;（3）用于主动热成像的热物理学：目标是可靠地测量经受热无损测试的大量新材料的热特性;需要热特性来馈送热模拟和缺陷表征代码。(4)设计低成本的检测系统：目标是设计低成本的红外热成像装置，可供负担不起高端设备的加拿大中小型公司使用。强大的内置处理与“微型”非制冷红外摄像机的新技术相结合将导致此类系统的发展。