sound-ranging location
简明释义
声波测距定位
英英释义
例句
1.The military relies on sound-ranging location to track missile launches from submarines.
军方依赖声测定位来追踪潜艇发射的导弹。
2.The naval officers used a sound-ranging location to determine the position of the enemy submarine.
海军官员使用声测定位来确定敌潜艇的位置。
3.In the training exercise, the team practiced using sound-ranging location techniques to locate underwater objects.
在训练演习中,团队练习使用声测定位技术来定位水下物体。
4.The researchers developed a new algorithm for improving sound-ranging location accuracy in marine environments.
研究人员开发了一种新算法,以提高海洋环境中声测定位的准确性。
5.Using sound-ranging location, scientists can map the ocean floor with high precision.
利用声测定位,科学家可以高精度地绘制海底地图。
作文
In the realm of modern technology, the concept of sound-ranging location has emerged as a pivotal method for determining the precise position of objects or individuals using sound waves. This technique harnesses the properties of sound to measure distances and locate sources of noise, making it invaluable in various fields such as navigation, military operations, and even wildlife research. Understanding how sound-ranging location works can provide insights into its applications and significance in our daily lives.To begin with, the fundamental principle behind sound-ranging location lies in the speed of sound. Sound travels through different mediums at varying speeds, but in air, it moves at approximately 343 meters per second at room temperature. By emitting sound waves from a known point and measuring the time it takes for these waves to bounce back after hitting an object, one can calculate the distance to that object. This distance measurement is crucial for pinpointing locations accurately.One of the most notable applications of sound-ranging location is in underwater exploration. Submarines and marine biologists often rely on sonar technology, which utilizes sound waves to detect and map underwater terrain and marine life. Sonar systems send out sound pulses and listen for echoes, allowing researchers to create detailed maps of the ocean floor and locate schools of fish or other aquatic organisms. This application highlights the importance of sound-ranging location in advancing our understanding of underwater ecosystems.Moreover, in military contexts, sound-ranging location plays a critical role in identifying the position of enemy artillery or aircraft. By analyzing the sound produced by gunfire or engine noise, military units can triangulate the source's position, enabling them to respond effectively. This capability not only enhances strategic planning but also improves the safety of personnel on the ground.In addition to these applications, sound-ranging location is also finding its way into everyday technology. For instance, smartphones are equipped with microphones and speakers that can utilize similar principles to enhance location-based services. By analyzing ambient sounds, apps can provide users with information about their surroundings or help them navigate unfamiliar areas. This integration of sound-ranging location into consumer technology illustrates its versatility and potential for improving user experiences.Furthermore, researchers are exploring innovative uses of sound-ranging location in wildlife conservation. By placing microphones in natural habitats, scientists can monitor animal populations and their behaviors through sound analysis. This non-invasive method allows for better tracking of endangered species and helps in formulating effective conservation strategies.In conclusion, the concept of sound-ranging location is a remarkable demonstration of how sound can be utilized for various practical purposes. From underwater exploration to military applications and everyday technology, the ability to determine locations based on sound waves has proven to be an essential tool in multiple domains. As technology continues to evolve, the potential for sound-ranging location to contribute to new advancements and discoveries remains vast, promising exciting developments for the future.
在现代科技领域,声波定位的概念作为一种关键方法,利用声波确定物体或个体的精确位置。该技术利用声音的特性来测量距离和定位噪音源,使其在导航、军事行动甚至野生动物研究等多个领域中变得不可或缺。理解声波定位的工作原理能够为我们提供对其应用和在日常生活中重要性的深入见解。首先,声波定位的基本原理在于声音的传播速度。声音在不同介质中的传播速度各不相同,但在空气中,其速度约为343米/秒(在室温下)。通过从已知点发出声波,并测量这些波碰撞物体后返回所需的时间,可以计算出到该物体的距离。这种距离测量对准确定位至关重要。声波定位最显著的应用之一是在水下探索中。潜艇和海洋生物学家通常依赖声纳技术,该技术利用声波来探测和绘制水下地形及海洋生物。声纳系统发出声脉冲并监听回声,从而使研究人员能够创建详细的海底地图,并定位鱼群或其他水生生物。这一应用凸显了声波定位在推动我们理解水下生态系统中的重要性。此外,在军事背景下,声波定位在识别敌方火炮或飞机的位置方面发挥着关键作用。通过分析枪声或引擎噪音所产生的声音,军事单位可以三角测量源头的位置,从而有效应对。这种能力不仅增强了战略规划,还提高了地面人员的安全性。除了这些应用之外,声波定位也逐渐融入日常技术。例如,智能手机配备了麦克风和扬声器,可以利用类似的原理来增强基于位置的服务。通过分析环境声音,应用程序可以向用户提供有关周围环境的信息或帮助他们在陌生地区导航。这种将声波定位整合到消费技术中的方式,展示了其多样性和改善用户体验的潜力。此外,研究人员正在探索在野生动物保护中创新使用声波定位的方法。通过在自然栖息地中放置麦克风,科学家可以通过声音分析监测动物种群及其行为。这种非侵入性的方法允许更好地追踪濒危物种,并有助于制定有效的保护策略。总之,声波定位的概念是声音如何被用于各种实际目的的一个显著示例。从水下探索到军事应用,再到日常技术,基于声波确定位置的能力已被证明是多个领域的重要工具。随着技术的不断发展,声波定位在新进展和发现中的潜力仍然广阔,为未来的激动人心的发展承诺。
