CURVATURE EFFECT QUANTIFICATION FOR IN-VIVO IR THERMOGRAPHY.

Tze-Yuan Cheng, Daxiang Deng, Cila Herman
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引用次数: 26

Abstract

Medical Infrared (IR) Imaging has become an important diagnostic tool over recent years. However, one underlying problem in medical diagnostics is associated with accurate quantification of body surface temperatures. This problem is caused by the artifacts induced by the curvature of objects, which leads to inaccurate temperature mapping and biased diagnostic results. Therefore, in our study, an experiment-based analysis is conducted to address the curvature effects toward the 3D temperature reconstruction of the IR thermography image. For quantification purposes, an isothermal copper plate with flat surface, and a cylindrical metal container filled with water are imaged. For the flat surface, the tilting angle measured from camera axis was varied incrementally from 0° to 60 °, such that the effects of surface viewing angle and travel distance on the measured temperature can be explored. On the cylindrical curved surface, the points viewed from 0° to 90° with respect to the camera axis are simultaneously imaged at different temperature levels. The experimental data obtained for the flat surface indicate that both viewing angle and distance effects become noticeable for angles over 40 °. The travel distance contributes a minor change when compared with viewing angle. The experimental results from the curved surface indicate that the curvature effect becomes pronounced when the viewing angle is larger than 60 °. The measurement error on the curved surface is compared with the simulation using the non-dielectric model, and the normalized temperature difference relative to 0° viewing angle was analyzed at six temperature levels. These results indicate that the linear formula associated with directional emissivity is a reasonable approximation for the measurement error, and the normalized error curves change consistently with viewing angle at various temperatures. Therefore, the analysis in this study implies that the directional emissivity based on the non-dielectric model can be applied for the calibration of measurement error. The normalized error curve serves as a consistent basis to correct the measurement error due to curvature artifacts.

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体内红外热成像曲率效应的量化。
近年来,医用红外成像已成为重要的诊断工具。然而,医学诊断中的一个潜在问题与体表温度的准确量化有关。该问题是由物体曲率引起的伪影引起的,它导致温度映射不准确和诊断结果有偏差。因此,在我们的研究中,进行了基于实验的分析,以解决曲率对红外热成像图像的三维温度重建的影响。为定量起见,对平面等温铜板和盛满水的圆柱形金属容器进行成像。对于平面,从相机轴测量的倾斜角从0°到60°递增,从而可以探索表面视角和行进距离对测量温度的影响。在圆柱形曲面上,相对于相机轴0°到90°观察的点在不同温度水平下同时成像。在平面上得到的实验数据表明,当角度大于40°时,视角和距离的影响都很明显。与视角相比,行进距离的变化较小。在曲面上的实验结果表明,当视角大于60°时,曲率效应变得明显。比较了曲面测量误差与非介电模型模拟误差,分析了6个温度水平下相对于0°视角的归一化温差。这些结果表明,定向发射率的线性公式是测量误差的合理近似,在不同温度下,归一化误差曲线随视角的变化是一致的。因此,本研究的分析表明,基于非介电模型的定向发射率可以用于测量误差的标定。归一化误差曲线作为校正曲率伪影引起的测量误差的一致基础。
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