azimuthal control

简明释义

方位控制;

英英释义

例句

1.During the experiment, we had to ensure azimuthal control was maintained for accurate data collection.

在实验过程中，我们必须确保维持方位控制以便准确收集数据。

2.The telescope's design includes a mechanism for azimuthal control to track celestial objects.

望远镜的设计包括一个机制，用于跟踪天体的方位控制。

3.The satellite's navigation system requires precise azimuthal control to maintain its orbit.

卫星的导航系统需要精确的方位控制以维持其轨道。

4.In robotics, azimuthal control helps the robot accurately orient itself in a 3D space.

在机器人技术中，方位控制帮助机器人准确地在三维空间中定位。

5.The aircraft's autopilot features advanced azimuthal control for better flight stability.

飞机的自动驾驶仪配备了先进的方位控制以提高飞行稳定性。

作文

In the realm of navigation and aerospace engineering, the term azimuthal control refers to the ability to manage and adjust the orientation of a vehicle or system in relation to the horizontal plane. This concept is crucial for various applications, including satellite positioning, missile guidance, and even in everyday technologies like smartphones. Understanding azimuthal control allows engineers and scientists to design systems that can maintain a specific direction while compensating for external factors such as wind or gravitational pull.One of the most significant aspects of azimuthal control is its application in satellite technology. Satellites orbiting the Earth must maintain precise orientations to ensure their instruments function correctly. For instance, a weather satellite needs to point its sensors directly at the Earth to gather accurate data. To achieve this, engineers implement azimuthal control mechanisms that utilize gyroscopes and reaction wheels, allowing the satellite to rotate along its axis without changing its altitude.Moreover, azimuthal control is vital in the field of missile guidance systems. Missiles must be able to navigate through the atmosphere and reach their targets with high precision. This is accomplished through a combination of onboard sensors that provide real-time data about the missile's position and orientation. By using azimuthal control, the guidance system can make necessary adjustments during flight, ensuring that the missile stays on course despite any disturbances it may encounter.In addition to aerospace applications, azimuthal control is also relevant in robotics. Autonomous robots often need to navigate complex environments, requiring them to adjust their orientation frequently. For example, a robotic vacuum cleaner must determine its position within a room and decide the best path to clean efficiently. By employing azimuthal control, these robots can turn and pivot accurately, optimizing their cleaning routes and avoiding obstacles.The concept of azimuthal control extends beyond technical fields; it can also be applied metaphorically in our daily lives. Just as a satellite or missile needs to maintain its direction, individuals must often exercise control over their own paths. Whether it's in career choices, personal relationships, or life goals, having a clear sense of direction and the ability to adjust when necessary is crucial for success.In conclusion, azimuthal control is a fundamental principle in navigation, aerospace engineering, and robotics, among other fields. Its importance cannot be overstated, as it enables systems to maintain orientation and direction in various environments. As technology continues to advance, the methods and techniques used to achieve azimuthal control will likely evolve, leading to even greater precision and efficiency in numerous applications. Understanding this concept not only enhances our grasp of technical systems but also serves as a reminder of the importance of direction and adaptability in our own lives.

在导航和航空航天工程领域，术语azimuthal control指的是管理和调整车辆或系统相对于水平面的方向的能力。这个概念对于各种应用至关重要，包括卫星定位、导弹制导，甚至在智能手机等日常技术中也有应用。理解azimuthal control使工程师和科学家能够设计能够在补偿外部因素（如风或重力影响）的情况下保持特定方向的系统。azimuthal control最重要的一个方面是其在卫星技术中的应用。绕地球轨道飞行的卫星必须保持精确的方向，以确保其仪器正常工作。例如，气象卫星需要将传感器直接对准地球，以收集准确的数据。为了实现这一点，工程师实施了使用陀螺仪和反作用轮的azimuthal control机制，使卫星能够沿其轴旋转而不改变高度。此外，azimuthal control在导弹制导系统中也至关重要。导弹必须能够在大气中导航并以高精度到达目标。这是通过一系列机载传感器来完成的，这些传感器提供关于导弹位置和方向的实时数据。通过使用azimuthal control，制导系统可以在飞行过程中进行必要的调整，确保导弹在遇到任何干扰时保持航向。除了航空航天应用，azimuthal control在机器人技术中也很相关。自主机器人经常需要在复杂环境中导航，因此需要频繁调整其方向。例如，机器人吸尘器必须确定其在房间内的位置，并决定最佳的清洁路径。通过采用azimuthal control，这些机器人能够准确地转向和旋转，优化清洁路线并避免障碍物。azimuthal control的概念不仅限于技术领域；它也可以在我们的日常生活中隐喻性地应用。正如卫星或导弹需要保持其方向一样，个人在生活中也常常需要控制自己的道路。无论是在职业选择、个人关系还是生活目标上，拥有明确的方向感和在必要时进行调整的能力对于成功至关重要。总之，azimuthal control是导航、航空航天工程和机器人等多个领域的基本原则。其重要性不容忽视，因为它使系统能够在各种环境中保持方向和航向。随着技术的不断进步，实现azimuthal control的方法和技术可能会不断演变，从而在众多应用中带来更大的精度和效率。理解这一概念不仅增强了我们对技术系统的理解，也提醒我们在自己的生活中方向感和适应能力的重要性。