spatial resolving power

简明释义

空间分辨能力

英英释义

例句

1.The new telescope has significantly improved its spatial resolving power, allowing astronomers to see distant galaxies more clearly.

这台新望远镜显著提高了它的空间分辨率，使天文学家能够更清晰地观察遥远的星系。

2.Microscopes with high spatial resolving power are essential for studying cellular structures.

具有高空间分辨率的显微镜对于研究细胞结构至关重要。

3.The spatial resolving power of the satellite images is crucial for urban planning.

卫星图像的空间分辨率对于城市规划至关重要。

4.In medical imaging, a higher spatial resolving power can lead to better diagnosis of tumors.

在医学成像中，更高的空间分辨率可以导致肿瘤更好的诊断。

5.The spatial resolving power of this radar system allows it to detect small objects in the ocean.

这个雷达系统的空间分辨率使其能够检测海洋中的小物体。

作文

In the realm of imaging and observation, the term spatial resolving power plays a crucial role in determining the clarity and detail of the images we capture. It refers to the ability of an imaging system, such as a microscope or telescope, to distinguish between two closely spaced objects. The higher the spatial resolving power, the finer the details that can be observed, which is vital in various scientific fields including biology, astronomy, and materials science.For example, in microscopy, spatial resolving power allows scientists to visualize cellular structures that are only a few nanometers apart. This capability is essential for understanding complex biological processes and for the development of new medical treatments. Without adequate spatial resolving power, researchers would struggle to identify important cellular components, leading to gaps in knowledge about how cells function and interact.Similarly, in astronomy, the spatial resolving power of telescopes determines our ability to observe distant celestial bodies. Telescopes with high spatial resolving power can differentiate between stars that are very close together in the night sky, enabling astronomers to study their properties and movements more accurately. This has profound implications for our understanding of the universe, including the formation of galaxies and the behavior of black holes.Moreover, advancements in technology have significantly enhanced the spatial resolving power of imaging systems. For instance, innovations in electron microscopy have allowed scientists to achieve resolutions that were previously thought impossible. This has opened new avenues for research, enabling the exploration of materials at atomic levels and enhancing our understanding of material properties.However, it is important to note that achieving high spatial resolving power often comes with challenges. Factors such as light diffraction, sample preparation, and environmental conditions can all impact the effectiveness of an imaging system. Therefore, researchers must carefully consider these elements when designing experiments and interpreting results.In conclusion, spatial resolving power is a fundamental concept in imaging that influences our ability to observe and understand the world around us. Whether in the microscopic world of cells or the vastness of space, the capability to resolve fine details is essential for advancing scientific knowledge. As technology continues to evolve, we can expect further improvements in spatial resolving power, paving the way for groundbreaking discoveries across various disciplines.

在成像和观察的领域中，术语空间分辨率在确定我们捕捉图像的清晰度和细节方面起着至关重要的作用。它指的是成像系统（如显微镜或望远镜）区分两个紧密相邻物体的能力。空间分辨率越高，能够观察到的细节就越精细，这在生物学、天文学和材料科学等多个科学领域中至关重要。例如，在显微镜学中，空间分辨率使科学家能够可视化仅相距几个纳米的细胞结构。这种能力对于理解复杂的生物过程和新医疗治疗的发展至关重要。如果没有足够的空间分辨率，研究人员将难以识别重要的细胞成分，从而导致对细胞如何运作和相互作用的知识存在空白。同样，在天文学中，望远镜的空间分辨率决定了我们观察遥远天体的能力。具有高空间分辨率的望远镜可以区分夜空中非常接近的星星，使天文学家能够更准确地研究它们的属性和运动。这对我们理解宇宙有深远的影响，包括星系的形成和黑洞的行为。此外，技术的进步显著增强了成像系统的空间分辨率。例如，电子显微镜的创新使科学家能够达到以前认为不可能的分辨率。这为研究开辟了新的途径，使我们能够在原子层面探索材料，并增强我们对材料特性的理解。然而，需要注意的是，实现高空间分辨率往往伴随着挑战。光衍射、样品准备和环境条件等因素都可能影响成像系统的有效性。因此，研究人员在设计实验和解释结果时必须仔细考虑这些因素。总之，空间分辨率是成像中的一个基本概念，它影响着我们观察和理解周围世界的能力。无论是在细胞的微观世界还是在浩瀚的宇宙中，解析细微细节的能力对于推动科学知识的进步至关重要。随着技术的不断发展，我们可以期待在空间分辨率方面进一步改善，为各个学科的突破性发现铺平道路。