satellite orbital track

简明释义

卫星轨道跟踪

英英释义

例句

1.Understanding the satellite orbital track 卫星轨道轨迹 is crucial for predicting satellite collisions.

理解卫星轨道轨迹 卫星轨道轨迹对于预测卫星碰撞至关重要。

2.Tracking the satellite orbital track 卫星轨道轨迹 helps in maintaining communication with the satellite.

跟踪卫星轨道轨迹 卫星轨道轨迹有助于保持与卫星的通信。

3.Engineers designed a new satellite with a unique satellite orbital track 卫星轨道轨迹 to improve data collection.

工程师设计了一颗新卫星，具有独特的卫星轨道轨迹 卫星轨道轨迹以改善数据收集。

4.The scientists monitored the satellite orbital track 卫星轨道轨迹 to ensure the satellite remained in its designated path.

科学家们监测了卫星轨道轨迹 卫星轨道轨迹以确保卫星保持在指定路径中。

5.The launch team calculated the satellite orbital track 卫星轨道轨迹 before sending the satellite into space.

发射团队在将卫星送入太空之前计算了卫星轨道轨迹 卫星轨道轨迹。

作文

The study of space has always fascinated humanity, and one of the most intriguing aspects of this field is the behavior of satellites in orbit. A satellite's movement through space is not random; it follows a specific path known as its satellite orbital track. This term refers to the trajectory that a satellite takes as it revolves around a celestial body, such as Earth. Understanding this concept is crucial for various applications, from telecommunications to weather forecasting.Satellites are launched into space for numerous purposes, including scientific research, navigation, and communication. Once a satellite reaches its designated altitude, it enters its satellite orbital track, which is determined by several factors, including the satellite's velocity, the gravitational pull of the Earth, and the altitude at which it orbits. There are different types of orbits, such as geostationary, polar, and low Earth orbit, each serving distinct functions.For instance, geostationary satellites maintain a fixed position relative to the Earth. They orbit at an altitude of approximately 35,786 kilometers above the equator, allowing them to stay over the same point on the Earth's surface. This is particularly useful for communication satellites, as they can provide continuous coverage to a specific area. The satellite orbital track of these satellites is circular and lies in the plane of the Earth's equator.In contrast, polar satellites have a different satellite orbital track. They travel over the poles and cover the entire surface of the Earth as the planet rotates beneath them. This type of orbit is essential for Earth observation satellites, which gather data on climate change, natural disasters, and land use. The ability to monitor the Earth from various angles is made possible by the specific satellite orbital track that these satellites follow.Moreover, understanding the satellite orbital track is vital for mission planning and satellite deployment. Engineers must calculate the optimal trajectory to ensure that the satellite reaches its intended orbit and remains operational. Any deviation from the planned satellite orbital track could result in mission failure, leading to significant financial loss and wasted resources.The implications of satellite orbits extend beyond scientific exploration and commercial interests; they also play a role in national security. Military satellites rely on precise satellite orbital tracks to gather intelligence and monitor potential threats. The ability to predict the movements of these satellites can provide strategic advantages in defense operations.As technology advances, the number of satellites in orbit continues to grow. This increase raises concerns about space debris and the potential for collisions. Understanding the satellite orbital track of each satellite is crucial for space traffic management, ensuring that satellites can safely navigate their paths without interfering with one another.In conclusion, the concept of satellite orbital track is fundamental to our understanding of how satellites operate in space. It encompasses the principles of physics, engineering, and environmental science, making it a multidisciplinary topic of great importance. As we continue to explore the cosmos and utilize satellite technology for various applications, a thorough understanding of satellite orbital track will be essential for future advancements in this exciting field.

太空研究一直以来都令全人类着迷，而这个领域中最引人入胜的方面之一就是卫星在轨道上的行为。卫星在太空中的运动并不是随机的；它遵循一条特定的路径，称为其卫星轨道轨迹。这个术语指的是卫星围绕天体（如地球）旋转时所采取的轨迹。理解这一概念对于各种应用至关重要，从电信到天气预报。卫星被发射到太空有许多目的，包括科学研究、导航和通信。一旦卫星达到指定高度，它就会进入其卫星轨道轨迹，而这一轨迹由多个因素决定，包括卫星的速度、地球的引力以及其轨道的高度。存在不同类型的轨道，例如静止轨道、极轨和低地球轨道，每种轨道都服务于不同的功能。例如，静止卫星相对于地球保持固定位置。它们在赤道上方约35,786公里的高度运行，使其能够始终位于地球表面的同一点上。这对于通信卫星特别有用，因为它们可以为特定区域提供持续覆盖。这些卫星的卫星轨道轨迹是圆形的，并位于地球赤道的平面上。相比之下，极轨卫星的卫星轨道轨迹则有所不同。它们越过极地，随着地球的自转覆盖整个地球表面。这种轨道类型对于地球观测卫星至关重要，这些卫星收集有关气候变化、自然灾害和土地利用的数据。从不同角度监测地球的能力正是由于这些卫星所遵循的特定卫星轨道轨迹。此外，了解卫星轨道轨迹对任务规划和卫星部署至关重要。工程师必须计算最佳轨迹，以确保卫星到达其预定轨道并保持正常运行。任何偏离计划的卫星轨道轨迹都可能导致任务失败，从而造成重大财务损失和资源浪费。卫星轨道的影响不仅限于科学探索和商业利益；它们在国家安全中也发挥着作用。军事卫星依赖精确的卫星轨道轨迹来收集情报和监视潜在威胁。预测这些卫星的运动能力可以为防御行动提供战略优势。随着技术的进步，轨道上卫星的数量不断增加。这一增长引发了关于太空垃圾和碰撞潜力的担忧。了解每颗卫星的卫星轨道轨迹对太空交通管理至关重要，确保卫星能够安全地导航其路径，而不相互干扰。总之，卫星轨道轨迹的概念是我们理解卫星如何在太空中运行的基础。它涵盖了物理学、工程学和环境科学的原理，使其成为一个跨学科的重要主题。随着我们继续探索宇宙并利用卫星技术进行各种应用，全面理解卫星轨道轨迹将对未来在这一激动人心的领域的进步至关重要。