angular velocity modulation

简明释义

角速度调制;

英英释义

例句

1.The game engine implemented angular velocity modulation to create more realistic character movements.

游戏引擎实现了角速度调制，以创造更真实的人物动作。

2.Engineers studied angular velocity modulation to enhance the performance of electric motors.

工程师们研究了角速度调制以提高电动机的性能。

3.The robotic arm utilized angular velocity modulation to adjust its speed during delicate operations.

这台机器人手臂利用角速度调制在精细操作中调整其速度。

4.By applying angular velocity modulation, the drone was able to perform complex aerial maneuvers.

通过应用角速度调制，无人机能够执行复杂的空中机动。

5.In aerospace engineering, angular velocity modulation is crucial for stabilizing spacecraft during flight.

在航空航天工程中，角速度调制对在飞行中稳定航天器至关重要。

作文

In the realm of physics and engineering, the concept of angular velocity modulation plays a crucial role in various applications. Angular velocity refers to the rate of rotation around an axis, measured in radians per second. When we talk about angular velocity modulation, we are discussing the intentional alteration of this rotational speed over time for specific purposes. This modulation can significantly impact the performance of mechanical systems, robotics, and even in fields like aerospace engineering.To understand the importance of angular velocity modulation, consider its application in robotic arms. These devices often need to perform tasks that require precision and adaptability. By modulating the angular velocity, engineers can control how quickly or slowly a robotic arm moves, allowing it to handle delicate objects without causing damage. For instance, if a robotic arm is tasked with picking up a fragile glass, it must move slowly at first to avoid breakage. Once the object is securely grasped, the arm can increase its speed to transport the item to its destination efficiently.Another significant application of angular velocity modulation is found in vehicles, particularly in the design of anti-lock braking systems (ABS). In such systems, the angular velocity of the wheels is constantly monitored. If the system detects that a wheel is about to lock up during braking, it can modulate the angular velocity by adjusting the brake pressure. This prevents skidding and allows the driver to maintain better control of the vehicle. Thus, angular velocity modulation not only enhances safety but also improves overall vehicle performance.In the field of aerospace, angular velocity modulation is essential for controlling the orientation and stability of spacecraft. Gyroscopes are often used to measure angular velocity, and by modulating this velocity, spacecraft can change their orientation in space. This capability is vital for maneuvering satellites or space probes, ensuring they remain on their intended paths. The precise control of angular velocity helps in executing complex maneuvers, such as docking with other spacecraft or adjusting orbits.Moreover, angular velocity modulation is also applicable in entertainment technology, particularly in virtual reality (VR) systems. In VR, users experience immersive environments that respond to their movements. By modulating the angular velocity of the virtual environment based on the user's head movements, developers can create a more realistic experience. This modulation helps prevent motion sickness, as it aligns the user's visual input with their physical movements, resulting in a smoother and more enjoyable experience.In conclusion, angular velocity modulation is a fundamental concept that impacts a wide range of technologies and industries. From robotics to automotive safety and aerospace navigation, the ability to control and adjust angular velocity is essential for enhancing performance, safety, and user experience. As technology continues to advance, the significance of angular velocity modulation will likely grow, leading to even more innovative applications and improvements in various fields. Understanding this concept is vital for anyone interested in engineering, physics, or technology development. It not only broadens our comprehension of motion dynamics but also opens doors to future advancements that rely on precise control of rotational movement.

在物理和工程领域，角速度调制的概念在各种应用中发挥着至关重要的作用。角速度是指围绕某一轴线的旋转速率，以每秒弧度为单位进行测量。当我们谈论角速度调制时，我们讨论的是为了特定目的有意改变这种旋转速度。这个调制可以显著影响机械系统、机器人技术，甚至在航空航天工程等领域。为了理解角速度调制的重要性，可以考虑其在机器人手臂中的应用。这些设备常常需要执行要求精确和适应性的任务。通过调制角速度，工程师可以控制机器人手臂移动的快慢，使其能够安全地处理精细物体。例如，如果机器人手臂的任务是拾起一个易碎的玻璃杯，它必须首先缓慢移动以避免破损。一旦物体被安全抓住，手臂可以加快速度，将物品高效运输到目的地。角速度调制的另一个重要应用是在车辆设计中，特别是在防抱死刹车系统（ABS）中。在这种系统中，车轮的角速度会被持续监测。如果系统检测到某个轮子在刹车过程中即将锁死，它可以通过调整刹车压力来调制角速度。这可以防止打滑，并使驾驶员更好地控制车辆。因此，角速度调制不仅增强了安全性，还提高了整体车辆性能。在航空航天领域，角速度调制对于控制航天器的方向和稳定性至关重要。陀螺仪通常用于测量角速度，通过调制这一速度，航天器可以改变其在空间中的方向。这种能力对于操纵卫星或探测器至关重要，确保它们保持在预定轨道上。精确控制角速度有助于执行复杂的机动，例如与其他航天器对接或调整轨道。此外，角速度调制也适用于娱乐技术，尤其是在虚拟现实（VR）系统中。在VR中，用户体验到响应其运动的沉浸式环境。通过根据用户头部运动调制虚拟环境的角速度，开发者可以创造更真实的体验。这种调制有助于防止晕动病，因为它将用户的视觉输入与其身体运动对齐，从而产生更流畅、更愉悦的体验。总之，角速度调制是一个基本概念，影响着广泛的技术和行业。从机器人技术到汽车安全，再到航空航天导航，控制和调整角速度的能力对于提升性能、安全性和用户体验至关重要。随着技术的不断进步，角速度调制的重要性可能会增长，导致在各个领域更具创新性的应用和改进。理解这一概念对于任何对工程、物理或技术开发感兴趣的人来说都是至关重要的。它不仅拓宽了我们对运动动态的理解，还为依赖精确控制旋转运动的未来进步打开了大门。