off-axis angle

简明释义

偏轴角

英英释义

例句

1.The camera's lens was designed to reduce the off-axis angle 偏轴角 for clearer images.

相机的镜头设计旨在减少off-axis angle 偏轴角以获得更清晰的图像。

2.In optical systems, a small off-axis angle 偏轴角 can lead to significant aberrations.

在光学系统中，较小的off-axis angle 偏轴角可能会导致显著的像差。

3.The laser beam was adjusted to minimize the off-axis angle 偏轴角 for better precision.

激光束被调整以最小化off-axis angle 偏轴角以提高精度。

4.A high off-axis angle 偏轴角 can cause signal distortions in communication systems.

高的off-axis angle 偏轴角可能会导致通信系统中的信号失真。

5.Engineers must calculate the off-axis angle 偏轴角 when designing satellite dishes.

工程师在设计卫星天线时必须计算off-axis angle 偏轴角。

作文

In the realm of physics and engineering, understanding various angles and their implications is crucial for accurate measurements and designs. One such angle that often comes into play is the off-axis angle, which refers to the angle between a line of sight or an axis of measurement and the perpendicular line drawn from a point of interest to the reference axis. This concept is particularly significant in fields like optics, astronomy, and mechanical engineering. For instance, when designing telescopes, engineers must account for the off-axis angle to ensure that light from celestial objects is captured accurately, leading to clearer images. The importance of the off-axis angle extends beyond just telescopes; it plays a vital role in camera design as well. Photographers and videographers need to understand how the off-axis angle affects the composition and focus of their shots. If the camera is not aligned properly with the subject, the resulting image may suffer from distortion or loss of detail. Therefore, mastering the concept of the off-axis angle can greatly enhance the quality of visual media. Moreover, in mechanical engineering, the off-axis angle is critical when analyzing forces acting on rotating components. For example, in the design of gears and pulleys, engineers must consider how the off-axis angle influences the efficiency of power transmission. A small deviation from the optimal angle can lead to increased wear and tear on the machinery, ultimately affecting its performance and lifespan. In addition to practical applications, the off-axis angle also has theoretical implications. It challenges our understanding of spatial relationships and how we perceive angles in three-dimensional space. When we visualize objects, it is easy to overlook the impact of the off-axis angle, yet it can significantly alter our interpretation of depth and perspective. Artists and architects often manipulate the off-axis angle to create compelling visual narratives and structures that engage viewers on multiple levels. Furthermore, the off-axis angle is essential in the field of robotics. As robots interact with their environments, they must calculate the off-axis angle to navigate effectively. Whether it's picking up objects or maneuvering through complex spaces, understanding this angle allows robots to perform tasks with precision and accuracy. This knowledge is foundational for developing advanced robotic systems that can operate autonomously in dynamic settings. In conclusion, the off-axis angle is a multifaceted concept that permeates various disciplines, from optics and photography to engineering and robotics. Its significance cannot be overstated, as it influences everything from the clarity of astronomical images to the efficiency of mechanical systems. By grasping the nuances of the off-axis angle, professionals across fields can enhance their work and contribute to advancements in technology and art alike. Understanding this angle not only improves technical skills but also enriches our appreciation of the complexities of the world around us.

在物理和工程领域，理解各种角度及其影响对于准确的测量和设计至关重要。其中一个经常出现的角度是离轴角，它指的是视线或测量轴与从感兴趣点垂直于参考轴绘制的线之间的角度。这个概念在光学、天文学和机械工程等领域尤为重要。例如，在设计望远镜时，工程师必须考虑离轴角，以确保捕捉到来自天体的光线，从而产生更清晰的图像。离轴角的重要性不仅限于望远镜，它在相机设计中也发挥着至关重要的作用。摄影师和摄像师需要理解离轴角如何影响他们拍摄的构图和焦点。如果相机没有正确对齐主题，所产生的图像可能会遭受失真或细节丧失。因此，掌握离轴角的概念可以极大提高视觉媒体的质量。此外，在机械工程中，离轴角在分析作用于旋转部件的力时至关重要。例如，在齿轮和滑轮的设计中，工程师必须考虑离轴角如何影响动力传输的效率。即使是微小的偏差也可能导致机械设备的磨损加剧，从而影响其性能和寿命。除了实际应用外，离轴角还有理论意义。它挑战了我们对空间关系的理解，以及我们如何在三维空间中感知角度。当我们可视化物体时，很容易忽视离轴角的影响，但它可以显著改变我们对深度和透视的解读。艺术家和建筑师常常操纵离轴角以创建引人注目的视觉叙事和结构，吸引观众在多个层面上参与。此外，离轴角在机器人领域也是必不可少的。当机器人与环境互动时，它们必须计算离轴角以有效导航。无论是拾取物体还是在复杂空间中移动，理解这一角度使机器人能够精确和准确地执行任务。这一知识是开发能够在动态环境中自主操作的先进机器人系统的基础。总之，离轴角是一个多方面的概念，渗透到光学、摄影、工程和机器人等各个学科。它的重要性不容小觑，因为它影响着从天文图像的清晰度到机械系统的效率等方方面面。通过掌握离轴角的细微差别，各领域的专业人士可以提升他们的工作，并为技术和艺术的进步做出贡献。理解这一角度不仅提高了技术技能，也丰富了我们对周围世界复杂性的欣赏。