hyperbolic navigation system

简明释义

双曲线导航系统

英英释义

例句

1.The ship relied on a hyperbolic navigation system to accurately determine its position at sea.

这艘船依靠双曲线导航系统准确确定其在海上的位置。

2.The development of the hyperbolic navigation system has revolutionized maritime navigation.

双曲线导航系统的发展彻底改变了海洋导航。

3.Using a hyperbolic navigation system, the aircraft was able to navigate through challenging weather conditions.

利用双曲线导航系统，飞机能够在复杂的天气条件下导航。

4.The hyperbolic navigation system provides real-time location data for emergency responders.

该双曲线导航系统为紧急救援人员提供实时位置信息。

5.Maritime agencies often use a hyperbolic navigation system for tracking vessels in busy shipping lanes.

海事机构通常使用双曲线导航系统来跟踪繁忙航道中的船只。

作文

In the realm of navigation, various systems have been developed to help individuals and vehicles find their way across vast distances. One such innovative system is the hyperbolic navigation system. This technology has played a crucial role in maritime and aerial navigation, allowing for accurate positioning and distance measurement without the need for extensive infrastructure. The hyperbolic navigation system operates on the principle of hyperbolas, which are geometric shapes formed by the intersection of two conic sections. By utilizing signals from multiple locations, this system can determine the position of a receiver based on the time it takes for the signals to travel from the transmitters to the receiver. Historically, the hyperbolic navigation system was first implemented in the early 20th century. It gained prominence with the advent of radio technology, which allowed for more precise measurements of time and distance. The most famous example of this system is the LORAN (Long Range Navigation) system, which was widely used during World War II and beyond. LORAN stations would emit radio signals that could be triangulated by receivers on ships or aircraft, enabling them to pinpoint their location with remarkable accuracy.The mathematical foundation of the hyperbolic navigation system lies in the principles of geometry and time measurement. When a signal is transmitted from a source, it travels at a known speed, typically the speed of light. By measuring the time it takes for the signal to reach the receiver, one can calculate the distance from the transmitter. With signals from at least two transmitters, the receiver can establish its position using hyperbolic lines of position. These lines create a hyperbola on a map, indicating where the receiver could be located based on the time differences of the received signals.Moreover, the hyperbolic navigation system is not limited to just maritime and aerial applications; it also finds use in various fields such as surveying, geophysics, and even in some modern-day GPS technologies. While GPS relies on satellites and trilateration, the fundamental concepts of hyperbolic navigation still underpin many of these advanced systems. As technology has evolved, so too has the hyperbolic navigation system. Modern advancements have led to improved accuracy and reliability, making it an invaluable tool for navigation in challenging environments. For instance, in areas where GPS signals may be weak or obstructed, hyperbolic navigation can provide a reliable alternative. In conclusion, the hyperbolic navigation system represents a significant leap in the field of navigation technology. Its ability to accurately determine positions through the use of hyperbolas and time measurements has transformed how we navigate our world. As we continue to explore new frontiers, understanding and utilizing systems like the hyperbolic navigation system will be essential for safe and efficient travel across land, sea, and air.

在导航领域，各种系统已经被开发出来，以帮助个人和车辆在广阔的距离中找到方向。其中一种创新系统是双曲导航系统。这项技术在海洋和航空导航中发挥了关键作用，允许在没有大量基础设施的情况下进行准确定位和距离测量。双曲导航系统基于双曲线的原理，双曲线是由两个圆锥曲线的交集形成的几何形状。通过利用来自多个位置的信号，该系统可以根据信号从发射器到接收器所需的时间来确定接收器的位置。历史上，双曲导航系统首次在20世纪初实施。随着无线电技术的出现，它在精确测量时间和距离方面获得了显著的关注。最著名的例子是LORAN（长距离导航）系统，该系统在第二次世界大战及其之后被广泛使用。LORAN站会发出无线电信号，船只或飞机上的接收器可以对这些信号进行三角测量，从而使它们能够以惊人的准确性确定自己的位置。双曲导航系统的数学基础在于几何学和时间测量的原理。当信号从源头发出时，它以已知的速度传播，通常是光速。通过测量信号到达接收器所需的时间，可以计算出与发射器的距离。通过来自至少两个发射器的信号，接收器可以使用双曲线位置线建立其位置。这些线在地图上形成一条双曲线，指示接收器根据接收到的信号的时间差可能位于何处。此外，双曲导航系统不仅限于海洋和航空应用；它还在测量、地球物理学等各个领域中得到应用，甚至在一些现代GPS技术中也有所涉及。尽管GPS依赖于卫星和三边测量，但双曲导航的基本概念仍然支撑着许多这些先进系统。随着技术的发展，双曲导航系统也不断演变。现代进步导致了更高的准确性和可靠性，使其成为在挑战环境中导航的宝贵工具。例如，在GPS信号可能微弱或被阻挡的地区，双曲导航可以提供可靠的替代方案。总之，双曲导航系统代表了导航技术领域的重要飞跃。它通过使用双曲线和时间测量准确确定位置的能力，改变了我们导航世界的方式。随着我们继续探索新的前沿，理解和利用像双曲导航系统这样的系统将对安全和高效的陆地、海洋和空中旅行至关重要。