resolution limit
简明释义
分辨限度
英英释义
例句
1.The camera's resolution limit 分辨率限制 affects the quality of the images it can capture.
相机的分辨率限制影响它能够捕捉的图像质量。
2.The resolution limit 分辨率限制 of a digital display impacts how clear text and images appear.
数字显示器的分辨率限制影响文本和图像的清晰度。
3.In microscopy, the resolution limit 分辨率限制 defines the smallest detail that can be observed.
在显微镜学中,分辨率限制定义了可以观察到的最小细节。
4.When printing, the resolution limit 分辨率限制 of the printer determines how sharp the final print will be.
在打印时,打印机的分辨率限制决定了最终打印的清晰度。
5.In satellite imagery, the resolution limit 分辨率限制 determines how much detail can be seen on the ground.
在卫星图像中,分辨率限制决定了地面上可以看到多少细节。
作文
In the world of technology and science, the term resolution limit refers to the smallest detail that can be distinguished in an image or a measurement. This concept is crucial in various fields such as photography, microscopy, and even astronomy. Understanding the resolution limit is essential for researchers and professionals who rely on visual data to draw conclusions and make informed decisions. For instance, in microscopy, the resolution limit determines how closely we can observe tiny structures within a cell. The ability to see these details can significantly impact biological research, leading to discoveries about cellular processes and disease mechanisms. If the resolution limit is too low, important features may be missed, resulting in incomplete or inaccurate data. Similarly, in photography, the resolution limit affects the quality of images captured by cameras. Higher resolution allows for more detail in photographs, making them sharper and more vibrant. Photographers often strive to push the boundaries of the resolution limit, using high-quality lenses and sensors to achieve stunning results. A photograph that exceeds the resolution limit may appear pixelated or blurry, detracting from its overall impact. In astronomy, the resolution limit plays a critical role in our understanding of the universe. Telescopes have specific resolution limits that dictate how clearly we can observe distant stars and galaxies. Advances in technology have allowed astronomers to enhance the resolution limit of telescopes, leading to groundbreaking discoveries about the cosmos. For example, the Hubble Space Telescope has provided images of celestial objects with unprecedented clarity, enabling scientists to study phenomena that were previously beyond our reach. The resolution limit is not just a technical specification; it also influences how we perceive and interpret the world around us. In digital media, the resolution limit affects everything from video streaming to virtual reality experiences. As technology continues to advance, the demand for higher resolutions grows, pushing the boundaries of what is possible. Moreover, understanding the resolution limit is vital for industries that rely on precise measurements and data analysis. In fields like engineering and manufacturing, knowing the resolution limit of instruments can determine the success of a project. For instance, in the production of microchips, even the slightest deviation beyond the resolution limit can lead to significant failures in functionality. In conclusion, the concept of resolution limit is integral to various scientific and technological domains. It defines the boundaries of what we can observe and measure, influencing the quality of data we gather. As we continue to innovate and develop new technologies, understanding and overcoming the resolution limit will remain a key focus for researchers and professionals alike. By pushing these limits, we can unlock new possibilities and deepen our understanding of the world around us.
在科技和科学的世界中,术语分辨率极限指的是在图像或测量中可以区分的最小细节。这个概念在摄影、显微镜学甚至天文学等多个领域至关重要。理解分辨率极限对于依赖视觉数据进行结论和做出明智决策的研究人员和专业人士而言是必不可少的。例如,在显微镜学中,分辨率极限决定了我们观察细胞内微小结构的能力。观察这些细节的能力可以显著影响生物研究,导致对细胞过程和疾病机制的发现。如果分辨率极限过低,重要特征可能会被遗漏,从而导致数据不完整或不准确。同样,在摄影中,分辨率极限影响相机捕捉图像的质量。更高的分辨率允许照片中包含更多细节,使其更加清晰和生动。摄影师通常努力突破分辨率极限,使用高质量的镜头和传感器来获得令人惊叹的效果。超过分辨率极限的照片可能会显得像素化或模糊,从而削弱其整体影响。在天文学中,分辨率极限在我们理解宇宙方面发挥着关键作用。望远镜具有特定的分辨率极限,决定了我们观察遥远星星和星系的清晰度。技术的进步使天文学家能够增强望远镜的分辨率极限,从而导致关于宇宙的突破性发现。例如,哈勃太空望远镜提供了前所未有的天体图像,使科学家能够研究以前无法接触到的现象。分辨率极限不仅是一项技术规格,它还影响我们如何感知和解释周围的世界。在数字媒体中,分辨率极限影响从视频流到虚拟现实体验的方方面面。随着技术的不断进步,对更高分辨率的需求不断增长,推动着可能性的边界。此外,理解分辨率极限对于依赖精确测量和数据分析的行业至关重要。在工程和制造等领域,了解仪器的分辨率极限可以决定项目的成功。例如,在微芯片的生产中,即使是超出分辨率极限的微小偏差也可能导致功能上的重大失败。总之,分辨率极限的概念在各个科学和技术领域中是不可或缺的。它定义了我们能够观察和测量的边界,影响我们收集的数据的质量。随着我们继续创新和开发新技术,理解和克服分辨率极限将始终是研究人员和专业人士关注的重点。通过突破这些极限,我们可以解锁新的可能性,深化对周围世界的理解。
