infrared tomography

简明释义

红外线断层摄影术

英英释义

例句

1.The construction team employed infrared tomography to identify moisture issues within the building's walls.

施工团队使用红外断层成像来识别建筑墙体内的潮湿问题。

2.Using infrared tomography, scientists can monitor temperature variations in geological formations.

科学家可以使用红外断层成像监测地质构造中的温度变化。

3.In medical imaging, infrared tomography can help detect tumors at an early stage.

在医学成像中，红外断层成像可以帮助早期发现肿瘤。

4.The researchers used infrared tomography to analyze the internal structures of the ancient artifacts.

研究人员使用红外断层成像分析古代文物的内部结构。

5.The automotive industry is now integrating infrared tomography for non-destructive testing of vehicle components.

汽车行业现在正在整合红外断层成像用于车辆部件的无损检测。

作文

Infrared technology has transformed various fields, from medicine to environmental science. One of the most significant advancements in this area is infrared tomography, which allows for detailed imaging of objects based on their thermal emissions. This innovative technique utilizes infrared radiation to create images that reveal temperature variations within an object. By capturing these thermal patterns, infrared tomography provides valuable insights into the internal structures and conditions of materials and living organisms.In medical applications, infrared tomography is used to detect tumors and other abnormalities in the body. Traditional imaging techniques, such as X-rays and MRIs, often require invasive procedures or exposure to radiation. In contrast, infrared tomography is non-invasive and safe, making it an attractive option for early diagnosis. For instance, researchers have demonstrated that infrared tomography can identify cancerous tissues by highlighting areas with abnormal heat signatures, which are indicative of increased metabolic activity in tumors.Beyond healthcare, infrared tomography plays a crucial role in the field of construction and engineering. It is employed to assess the integrity of buildings and infrastructure by detecting heat loss and moisture accumulation. This information is vital for maintaining energy efficiency and preventing structural damage. For example, using infrared tomography, inspectors can identify areas where insulation is lacking or where leaks may occur, allowing for timely repairs and improvements.Environmental scientists also leverage infrared tomography to monitor ecosystems and study climate change. By analyzing thermal images of forests, oceans, and urban areas, researchers can gain insights into temperature fluctuations and their effects on wildlife and vegetation. This data is essential for developing strategies to mitigate the impacts of global warming and preserve biodiversity.As technology advances, the applications of infrared tomography continue to expand. The integration of artificial intelligence and machine learning with infrared tomography is paving the way for more accurate and efficient analyses. These technologies can process vast amounts of thermal data, identifying patterns and anomalies that may be overlooked by human observers. Consequently, the combination of AI and infrared tomography is expected to enhance diagnostic capabilities in medicine and improve predictive models in environmental science.In conclusion, infrared tomography represents a groundbreaking advancement in imaging technology, with far-reaching implications across various domains. Its ability to provide non-invasive, detailed insights into temperature variations makes it a powerful tool in medicine, construction, and environmental monitoring. As research and technology continue to evolve, infrared tomography will undoubtedly play an increasingly vital role in our understanding of complex systems and the challenges we face in the modern world.

红外技术已经改变了多个领域，从医学到环境科学。其中一个重要的进展是红外层析成像，它允许根据物体的热辐射进行详细成像。这种创新技术利用红外辐射创建图像，揭示物体内部的温度变化。通过捕捉这些热模式，红外层析成像提供了关于材料和生物体内部结构和状况的重要见解。在医疗应用中，红外层析成像被用来检测肿瘤和其他异常情况。传统的成像技术，如X光和MRI，通常需要侵入性程序或辐射暴露。相比之下，红外层析成像是非侵入性的且安全的，这使其成为早期诊断的理想选择。例如，研究人员已经证明，红外层析成像可以通过突出异常热信号来识别癌性组织，这些信号表明肿瘤的代谢活动增加。除了医疗，红外层析成像在建筑和工程领域也发挥着重要作用。它被用于评估建筑和基础设施的完整性，通过检测热量损失和湿气积聚。这些信息对于维护能效和防止结构损坏至关重要。例如，使用红外层析成像，检查员可以识别缺乏绝缘或可能发生泄漏的区域，从而及时进行修复和改进。环境科学家还利用红外层析成像来监测生态系统和研究气候变化。通过分析森林、海洋和城市地区的热图像，研究人员可以深入了解温度波动及其对野生动物和植被的影响。这些数据对于制定减缓全球变暖影响和保护生物多样性的战略至关重要。随着技术的进步，红外层析成像的应用继续扩展。将人工智能和机器学习与红外层析成像相结合，为更准确和高效的分析铺平了道路。这些技术可以处理大量热数据，识别模式和异常，人工观察者可能会忽视。因此，人工智能与红外层析成像的结合预计将增强医学诊断能力，并改善环境科学中的预测模型。总之，红外层析成像代表了成像技术的突破性进展，在各个领域具有深远的影响。它提供非侵入性、详细的温度变化洞察，使其成为医学、建筑和环境监测中的强大工具。随着研究和技术的不断发展，红外层析成像无疑将在我们理解复杂系统以及面对现代世界挑战方面发挥越来越重要的作用。