azimuth change pulse

简明释义

方位变化脉冲

英英释义

例句

1.To maintain communication, the ground station sends an azimuth change pulse to the satellite.

为了保持通信，地面站向卫星发送方位角变化脉冲。

2.Engineers analyzed the azimuth change pulse data to improve the accuracy of the radar system.

工程师分析了方位角变化脉冲数据，以提高雷达系统的精确度。

3.During the test, the azimuth change pulse was triggered to see how the system responded.

在测试过程中，触发了方位角变化脉冲以观察系统的反应。

4.The drone adjusted its flight path using the azimuth change pulse received from its sensors.

无人机利用从传感器接收到的方位角变化脉冲调整飞行路径。

5.The satellite's navigation system uses an azimuth change pulse to adjust its trajectory.

卫星的导航系统使用方位角变化脉冲来调整其轨道。

作文

In the realm of navigation and astronomy, understanding various technical terms is crucial for both professionals and enthusiasts alike. One such term that often comes up in discussions about tracking and positioning systems is azimuth change pulse. This phrase refers to a specific type of signal used to indicate a change in the azimuth angle, which is the angle between a reference direction (usually north) and the line of sight to an object. The importance of this concept cannot be overstated, as it plays a vital role in various applications, including satellite communication, missile guidance, and even in some advanced automotive technologies.The azimuth change pulse can be thought of as a trigger or a marker that signifies when a system needs to adjust its orientation or focus. For example, in satellite systems, maintaining the correct azimuth is essential for ensuring that signals are directed accurately towards the intended target. When the satellite's position changes, or when it needs to reorient itself, a azimuth change pulse is generated to facilitate this adjustment. This pulse informs the onboard systems that a recalibration is necessary, allowing for precise tracking and communication.Moreover, the concept of azimuth change pulse is not limited to just satellites. In the field of military operations, particularly in missile guidance systems, accurate tracking of targets is paramount. Here, the azimuth change pulse serves as a critical component that helps in adjusting the trajectory of a missile in real-time. By analyzing the incoming pulses, the guidance system can determine whether the missile needs to alter its path to ensure a successful strike on the target.In addition to these applications, the azimuth change pulse finds relevance in various other technological advancements. For instance, in autonomous vehicles, accurate navigation is essential for safe operation. These vehicles rely on a combination of sensors and algorithms to determine their position and orientation. When a vehicle detects a need to change direction, a azimuth change pulse may be generated to signal the steering system to make the necessary adjustments. This ensures that the vehicle remains on the correct path and avoids obstacles, ultimately enhancing safety and efficiency.Understanding the mechanics behind the azimuth change pulse also opens up discussions about the underlying technology that makes these systems work. From the basic principles of trigonometry that govern how angles are measured, to the sophisticated algorithms used in modern computing, the implications of this term are vast and varied. Engineers and scientists continually strive to improve the accuracy and responsiveness of systems that utilize azimuth change pulse, leading to innovations that push the boundaries of what is possible in navigation and tracking technologies.In conclusion, the term azimuth change pulse encapsulates a fundamental aspect of navigation and positioning systems. Its role in facilitating accurate tracking and orientation adjustments is indispensable across multiple fields, from aerospace to automotive technology. As we continue to advance in our understanding of these systems, the significance of the azimuth change pulse will undoubtedly grow, paving the way for new developments that enhance our ability to navigate the world around us with precision and confidence.

在导航和天文学领域，理解各种技术术语对专业人士和爱好者来说都是至关重要的。一个在讨论跟踪和定位系统时经常出现的术语是方位角变化脉冲。这个短语指的是一种特定类型的信号，用于指示方位角的变化，方位角是参考方向（通常是北方）与视线到物体之间的角度。这一概念的重要性不容小觑，因为它在包括卫星通信、导弹制导甚至一些先进汽车技术等多种应用中发挥着重要作用。可以将方位角变化脉冲视为一个触发器或标记，表示系统需要调整其方向或焦点。例如，在卫星系统中，维持正确的方位角对于确保信号准确地传向目标至关重要。当卫星的位置发生变化或需要重新定向时，会生成方位角变化脉冲以便于这种调整。这个脉冲通知机载系统需要重新校准，从而实现精确的跟踪和通信。此外，方位角变化脉冲的概念并不仅限于卫星。在军事行动领域，特别是在导弹制导系统中，准确跟踪目标至关重要。在这里，方位角变化脉冲作为一个关键组件，帮助实时调整导弹的轨迹。通过分析输入脉冲，制导系统可以确定导弹是否需要改变路径，以确保成功打击目标。除了这些应用之外，方位角变化脉冲还在其他各种技术进步中具有相关性。例如，在自动驾驶汽车中，准确导航对于安全操作至关重要。这些车辆依赖于传感器和算法的组合来确定其位置和方向。当车辆检测到需要改变方向时，可能会生成方位角变化脉冲，以向转向系统发出信号，进行必要的调整。这确保了车辆保持在正确的路径上并避免障碍，最终提高了安全性和效率。了解方位角变化脉冲背后的机制也引发了关于使这些系统正常工作的基础技术的讨论。从控制角度测量的基本三角学原理，到现代计算中使用的复杂算法，这个术语的影响范围广泛而多样。工程师和科学家们不断努力提高利用方位角变化脉冲的系统的准确性和响应能力，推动了导航和跟踪技术的创新，突破了可能性的边界。总之，术语方位角变化脉冲概括了导航和定位系统的一个基本方面。它在促进准确跟踪和方向调整中的作用在多个领域中不可或缺，从航空航天到汽车技术。随着我们在理解这些系统方面的不断进步，方位角变化脉冲的重要性无疑会增加，为新发展铺平道路，从而增强我们以精确和自信的方式导航周围世界的能力。