rotating trace

简明释义

旋转扫描线

英英释义

例句

1.During the experiment, we observed the rotating trace 旋转轨迹 of the pendulum as it swung back and forth.

在实验中，我们观察到摆动时的rotating trace 旋转轨迹。

2.The robot arm followed a precise path, creating a rotating trace 旋转轨迹 in the air.

机器人手臂沿着精确的路径移动，在空中形成了一个rotating trace 旋转轨迹。

3.In our simulation, the rotating trace 旋转轨迹 of the planets helped visualize their orbits.

在我们的模拟中，行星的rotating trace 旋转轨迹 帮助我们可视化它们的轨道。

4.The artist used light to create a stunning rotating trace 旋转轨迹 on the canvas.

艺术家利用光线在画布上创造出惊艳的rotating trace 旋转轨迹。

5.The drone captured a video showing the rotating trace 旋转轨迹 of its flight pattern.

无人机拍摄了一段视频，展示了其飞行模式的rotating trace 旋转轨迹。

作文

The concept of a rotating trace is fascinating and can be observed in various fields, including physics, engineering, and even art. A rotating trace refers to the path that an object takes as it rotates around a central point or axis. This phenomenon can be seen in everyday life, from the way planets orbit the sun to the motion of a spinning top on a table. Understanding the rotating trace allows us to appreciate the dynamics of motion and the forces that govern it.In physics, the study of rotating trace is essential for understanding angular momentum and rotational dynamics. For instance, when a figure skater spins, they pull their arms in to increase their rotation speed. The rotating trace in this case would be the circular path described by the skater's body as they rotate. This principle can also be applied to celestial bodies, where the rotating trace of planets is determined by gravitational forces and their initial velocity. The beauty of this concept lies in its ability to connect various aspects of motion, illustrating how different forces interact to create complex movements.In engineering, the rotating trace is crucial in the design of machinery and vehicles. For example, in a car engine, the crankshaft rotates, creating a rotating trace that translates the linear motion of the pistons into rotational motion, ultimately driving the wheels. Understanding the rotating trace of these components helps engineers optimize performance and efficiency, ensuring that machines operate smoothly and effectively. Furthermore, in robotics, the rotating trace of robotic arms must be meticulously calculated to ensure precision in tasks such as assembly or surgery.Art also embraces the idea of rotating trace in various forms. Artists often use circular movements to create dynamic pieces that capture the viewer's attention. For instance, in kinetic sculptures, the rotating trace of moving parts adds an element of surprise and engagement, making the artwork come alive. The visual representation of a rotating trace can evoke emotions and provoke thought, showcasing the intersection of science and creativity.Moreover, the rotating trace can be observed in nature, where the patterns created by rotating objects can be both beautiful and functional. For example, the way leaves spiral around a stem or the formation of whirlpools in water illustrates the natural occurrence of rotating trace. These patterns not only serve aesthetic purposes but also play crucial roles in ecosystems, influencing processes such as pollination and nutrient distribution.In conclusion, the study of rotating trace is multifaceted, encompassing various disciplines and applications. From the mechanics of spinning objects in physics to the intricate designs in engineering and the expressive forms in art, the rotating trace offers a unique perspective on motion and interaction. By exploring this concept further, we can enhance our understanding of the world around us and appreciate the beauty found in the movement of both man-made and natural objects.

“旋转轨迹”的概念令人着迷，可以在物理学、工程学甚至艺术等多个领域中观察到。“旋转轨迹”是指物体围绕中心点或轴旋转时所经过的路径。这种现象可以在日常生活中看到，从行星围绕太阳的轨道到桌子上旋转的陀螺的运动。理解“旋转轨迹”使我们能够欣赏运动的动态及其所遵循的力量。在物理学中，研究“旋转轨迹”对于理解角动量和旋转动力学至关重要。例如，当花样滑冰运动员旋转时，他们会收紧手臂以增加旋转速度。在这种情况下，“旋转轨迹”就是运动员身体旋转时所描述的圆形路径。这个原理也可以应用于天体，其中行星的“旋转轨迹”由引力和初始速度决定。这个概念的美在于它能够连接运动的各个方面，说明不同的力量如何相互作用以创造复杂的运动。在工程学中，“旋转轨迹”对机械和车辆的设计至关重要。例如，在汽车发动机中，曲轴旋转，产生的“旋转轨迹”将活塞的线性运动转化为旋转运动，最终驱动车轮。理解这些组件的“旋转轨迹”帮助工程师优化性能和效率，确保机器平稳有效地运行。此外，在机器人技术中，机器人手臂的“旋转轨迹”必须经过精确计算，以确保在组装或手术等任务中的精准。艺术也在各种形式中接受了“旋转轨迹”的理念。艺术家们经常使用圆形运动来创作动态作品，以吸引观众的注意力。例如，在动感雕塑中，移动部件的“旋转轨迹”增添了一种惊喜和参与感，使艺术作品栩栩如生。“旋转轨迹”的视觉表现可以唤起情感并引发思考，展示科学与创造力的交汇。此外，自然界中也可以观察到“旋转轨迹”，其中由旋转物体形成的图案既美丽又实用。例如，叶子在茎上螺旋状生长或水中的漩涡形成都说明了“旋转轨迹”的自然发生。这些图案不仅具有美学功能，还在生态系统中发挥着关键作用，影响授粉和养分分配等过程。总之，“旋转轨迹”的研究是多方面的，涵盖了各种学科和应用。从物理学中旋转物体的力学到工程学中的复杂设计，再到艺术中的表现形式，“旋转轨迹”提供了对运动和互动的独特视角。通过进一步探索这一概念，我们可以增强对周围世界的理解，并欣赏到人造物体和自然物体运动中的美感。