radiometry

简明释义

英[reɪdɪˈɒmɪtri]美[reɪdɪˈɑːmɪtri]

n. 辐射线测定

英英释义

单词用法

同义词

反义词

例句

1.Moreover, the calibration scheme is outlined on the basis of the characteristics of radiometry for shooting range.

根据靶场辐射测量特点，设计了整体定标方案。

2.Based on the theory of radiometry, the measurement technique for linear response of ultraviolet ICCD (UV-ICCD) detector was studied and a comparative measurement method was presented.

以辐射度学为理论基础，研究了紫外ic CD (UV - ICCD)的线性测量技术，提出了比较测量方法。

3.In experiments, we used the 2793k halogen tungsten lamp to irradiate the detector of CCD143A and measured the values of photometry and radiometry. The correction of theory and...

在工作实验中，使用了2793K卤钨灯照射CCD143 A光电器件，同时分别测量了光度量与辐射度量，其结果与计算值相近。

4.Emissivity is an important parameter in radiometry.

比辐射率是辐射度学中的重要参量。

5.Quasi-optical networks (QON) were widely used in the remote sensing radiometry system embedded in the satellite platform.

准光系统广泛应用于星载遥感系统中。

6.Abstract: Quasi-optical networks (QON) were widely used in the remote sensing radiometry system embedded in the satellite platform.

摘要准光系统广泛应用于星载遥感系统中。

7.The field of radiometry 辐射测量 is essential for understanding how different materials absorb and emit radiation.

辐射测量领域对于理解不同材料如何吸收和发射辐射至关重要。

8.In astronomy, radiometry 辐射测量 helps scientists measure the brightness of celestial objects.

在天文学中，辐射测量帮助科学家测量天体的亮度。

9.The development of new sensors has advanced the accuracy of radiometry 辐射测量 in environmental monitoring.

新传感器的发展提高了环境监测中辐射测量的准确性。

10.Researchers utilize radiometry 辐射测量 to evaluate the energy output of solar panels.

研究人员利用辐射测量评估太阳能电池板的能量输出。

11.Understanding the principles of radiometry 辐射测量 is crucial for designing effective thermal imaging systems.

理解辐射测量的原理对于设计有效的热成像系统至关重要。

作文

Radiometry is a branch of science that deals with the measurement of optical radiation, which includes visible light as well as other forms of electromagnetic radiation. The importance of radiometry (辐射测量学) cannot be overstated, especially in fields such as astronomy, meteorology, and even in everyday applications like photography and display technologies. Understanding how to measure and quantify light can lead to advancements in technology and improvements in our understanding of the universe around us. One of the most significant applications of radiometry (辐射测量学) is in the field of astronomy. Astronomers rely heavily on the principles of radiometry (辐射测量学) to gather data from distant stars and galaxies. By measuring the amount of light that reaches Earth from these celestial bodies, scientists can infer important information about their composition, distance, and movement. This data is crucial for constructing models of the universe and understanding phenomena such as black holes and supernovae. In meteorology, radiometry (辐射测量学) plays a vital role in weather forecasting and climate studies. Satellites equipped with radiometers measure the Earth's radiation budget, which is essential for understanding energy balance and climate change. These measurements help meteorologists predict weather patterns and assess the impact of human activities on global warming. Without the insights provided by radiometry (辐射测量学), our ability to understand and respond to climate change would be significantly hindered. In the realm of technology, radiometry (辐射测量学) has influenced the development of various devices, including cameras and screens. Photographers utilize principles of radiometry (辐射测量学) to achieve the correct exposure in their images, ensuring that the photographs capture the intended brightness and contrast. Similarly, display manufacturers apply radiometry (辐射测量学) to create screens that accurately represent colors and brightness levels, enhancing the viewing experience for users. Moreover, radiometry (辐射测量学) is also critical in health and safety applications. For instance, in medical imaging, accurate measurements of radiation are essential to ensure patient safety while obtaining diagnostic images. Radiologists must understand the principles of radiometry (辐射测量学) to optimize imaging techniques and minimize exposure to harmful radiation. As we continue to advance technologically and scientifically, the relevance of radiometry (辐射测量学) will only grow. It serves as a bridge connecting various disciplines, from physics and engineering to environmental sciences and medicine. Education and research in radiometry (辐射测量学) are crucial for training the next generation of scientists and engineers who will tackle some of the most pressing challenges facing humanity today. In conclusion, radiometry (辐射测量学) is an essential field that underpins many aspects of modern science and technology. Its applications are vast and varied, impacting everything from our understanding of the cosmos to the way we interact with the environment and technology. As we delve deeper into the mysteries of light and radiation, the principles of radiometry (辐射测量学) will continue to illuminate our path forward.

辐射测量学是一个科学分支，处理光学辐射的测量，包括可见光和其他形式的电磁辐射。radiometry（辐射测量学）的重要性不容小觑，尤其在天文学、气象学以及日常应用如摄影和显示技术等领域。理解如何测量和量化光可以推动技术进步，并改善我们对周围宇宙的理解。 radiometry（辐射测量学）在天文学中的一个重要应用。天文学家在很大程度上依赖radiometry（辐射测量学）的原理来收集来自遥远星星和星系的数据。通过测量从这些天体到达地球的光的数量，科学家可以推断出关于它们的组成、距离和运动的重要信息。这些数据对于构建宇宙模型和理解黑洞和超新星等现象至关重要。 在气象学中，radiometry（辐射测量学）在天气预报和气候研究中发挥着至关重要的作用。配备辐射计的卫星测量地球的辐射预算，这对于理解能量平衡和气候变化至关重要。这些测量帮助气象学家预测天气模式并评估人类活动对全球变暖的影响。如果没有radiometry（辐射测量学）提供的见解，我们理解和应对气候变化的能力将受到重大阻碍。 在技术领域，radiometry（辐射测量学）影响了各种设备的发展，包括相机和屏幕。摄影师利用radiometry（辐射测量学）的原理来实现图像的正确曝光，确保照片捕捉到预期的亮度和对比度。同样，显示制造商应用radiometry（辐射测量学）来创建准确表示颜色和亮度水平的屏幕，增强用户的观看体验。 此外，radiometry（辐射测量学）在健康和安全应用中也至关重要。例如，在医学成像中，准确的辐射测量对于确保患者安全以及获取诊断图像至关重要。放射科医生必须理解radiometry（辐射测量学）的原理，以优化成像技术并最小化对有害辐射的暴露。 随着我们在技术和科学上的不断进步，radiometry（辐射测量学）的相关性只会增长。它作为连接物理学、工程学、环境科学和医学等多个学科的桥梁。教育和研究radiometry（辐射测量学）对于培养下一代科学家和工程师至关重要，他们将应对当今人类面临的一些最紧迫的挑战。 总之，radiometry（辐射测量学）是一个基本领域，支撑着现代科学和技术的许多方面。其应用广泛而多样，影响着从我们对宇宙的理解到我们与环境和技术的互动。随着我们深入探索光和辐射的奥秘，radiometry（辐射测量学）的原理将继续照亮我们前进的道路。