angle of minimum resolution

简明释义

最小分辨角;

英英释义

例句

1.Understanding the angle of minimum resolution 最小分辨率角 is crucial for improving image processing algorithms.

理解 最小分辨率角 最小分辨率角 对于改善图像处理算法至关重要。

2.When designing a camera system, engineers must consider the angle of minimum resolution 最小分辨率角 to ensure high-quality photos.

在设计相机系统时，工程师必须考虑 最小分辨率角 最小分辨率角 以确保高质量照片。

3.In satellite imaging, the angle of minimum resolution 最小分辨率角 affects the clarity of the captured images.

在卫星成像中，最小分辨率角 最小分辨率角 影响捕获图像的清晰度。

4.The angle of minimum resolution 最小分辨率角 can vary significantly between different optical devices.

不同光学设备之间的 最小分辨率角 最小分辨率角 可能会有显著差异。

5.Astronomers must calculate the angle of minimum resolution 最小分辨率角 to observe distant celestial bodies accurately.

天文学家必须计算 最小分辨率角 最小分辨率角 以准确观察遥远的天体。

作文

In the field of optics and imaging, the concept of the angle of minimum resolution plays a crucial role in determining how well we can distinguish between two closely spaced objects. This angle is defined as the smallest angle at which two points can be resolved as separate entities rather than appearing as a single blurred point. Understanding this concept is essential for various applications, including photography, microscopy, and even astronomy.To grasp the importance of the angle of minimum resolution, let us consider a practical example in photography. When capturing an image, the camera's lens must focus light from the scene onto the sensor. If the objects in the scene are too close together, the camera may not be able to resolve them clearly. This limitation is largely determined by the angle of minimum resolution, which is influenced by factors such as the aperture size of the lens and the wavelength of light being used.In microscopy, the angle of minimum resolution is even more critical. Microscopes are designed to magnify tiny specimens, allowing scientists to observe details that are invisible to the naked eye. The ability to resolve fine details depends on the microscope's numerical aperture and the wavelength of light used for illumination. A smaller angle of minimum resolution means that the microscope can distinguish between two points that are closer together, providing clearer and more detailed images of the specimen.Moreover, in astronomy, the angle of minimum resolution is vital for observing distant celestial bodies. Telescopes must have a sufficiently large aperture to gather enough light and achieve a small angle of minimum resolution. This allows astronomers to distinguish between stars that are very close together in the night sky. Without the ability to resolve these points of light, our understanding of the universe would be severely limited.The implications of the angle of minimum resolution extend beyond just scientific instruments. In everyday life, our own vision is subject to similar limitations. The human eye has a certain resolving power, which determines how clearly we can see objects that are close together. Factors such as lighting conditions, distance, and even individual differences in eyesight can affect our perception of the angle of minimum resolution.In conclusion, the angle of minimum resolution is a fundamental concept that impacts various fields, from photography to microscopy and astronomy. It defines the limits of our ability to discern details and plays a significant role in the design and function of optical instruments. As technology advances, understanding and improving the angle of minimum resolution will continue to enhance our ability to explore and understand the world around us. Whether we are capturing memories through a camera or exploring the depths of space, this concept remains a cornerstone of visual clarity and precision.

在光学和成像领域，最小分辨角的概念在确定我们能多好地区分两个紧密相邻的物体方面起着至关重要的作用。这个角度被定义为可以将两个点分辨为独立实体而不是看起来模糊成一个点的最小角度。理解这个概念对于各种应用至关重要，包括摄影、显微镜和天文学。为了更好地理解最小分辨角的重要性，让我们考虑一个摄影中的实际例子。当捕捉图像时，相机的镜头必须将场景中的光线聚焦到传感器上。如果场景中的物体太靠近，相机可能无法清晰地分辨它们。这种限制在很大程度上取决于最小分辨角，而且受镜头光圈大小和所用光波长等因素的影响。在显微镜学中，最小分辨角显得尤为关键。显微镜旨在放大微小样本，使科学家能够观察肉眼不可见的细节。分辨精细细节的能力取决于显微镜的数值孔径和用于照明的光波长。较小的最小分辨角意味着显微镜能够区分更靠近的两个点，从而提供样本的更清晰、更详细的图像。此外，在天文学中，最小分辨角对于观察遥远的天体至关重要。望远镜必须具有足够大的光圈，以收集足够的光并实现较小的最小分辨角。这使得天文学家能够区分夜空中非常接近的星星。如果没有分辨这些光点的能力，我们对宇宙的理解将受到严重限制。最小分辨角的影响不仅限于科学仪器。在日常生活中，我们自己的视力也受到类似的限制。人眼有一定的分辨能力，这决定了我们能多清楚地看到靠近的物体。照明条件、距离甚至个人视力差异等因素都可以影响我们对最小分辨角的感知。总之，最小分辨角是一个基本概念，影响着从摄影到显微镜学和天文学等多个领域。它定义了我们辨别细节的能力的极限，并在光学仪器的设计和功能中发挥着重要作用。随着技术的进步，理解和改善最小分辨角将继续增强我们探索和理解周围世界的能力。无论我们是在通过相机捕捉回忆，还是探索太空的深处，这一概念始终是视觉清晰度和精确性的基石。