sonic sounding
简明释义
回声测深法
英英释义
Sonic sounding refers to the use of sound waves, typically in the range of audible frequencies, to measure or analyze physical properties or phenomena. | 声波探测是指使用声波,通常是在可听频率范围内,用于测量或分析物理特性或现象。 |
例句
1.During the concert, the sonic sounding effects created an immersive experience for the audience.
在音乐会上,声波效果为观众创造了一种沉浸式体验。
2.The scientists used a device that emits sonic sounding waves to study the underwater ecosystem.
科学家们使用一种发出声波的设备来研究水下生态系统。
3.The new smartphone features a sonic sounding speaker system that enhances audio quality.
这款新智能手机配备了一个声波扬声器系统,提升了音质。
4.In the lab, researchers are exploring sonic sounding methods to improve communication with marine animals.
在实验室里,研究人员正在探索声波方法以改善与海洋动物的沟通。
5.The engineer explained how sonic sounding technology can help detect structural issues in buildings.
工程师解释了如何利用声波技术帮助检测建筑物的结构问题。
作文
In the realm of scientific exploration, the term sonic sounding refers to a method used to measure and analyze various properties of materials and environments through sound waves. This technique has been instrumental in fields such as oceanography, geology, and even medicine. By utilizing sonic sounding techniques, researchers can gather crucial data that would otherwise be difficult or impossible to obtain. For instance, in oceanography, sonic sounding is used to map the seafloor and study underwater features by sending sound waves from a ship and measuring the time it takes for the echoes to return. This information is vital for understanding marine ecosystems, navigation routes, and geological formations beneath the water's surface.Moreover, sonic sounding plays a significant role in the field of geophysics. Scientists utilize this method to explore subsurface structures, including oil and gas reserves, mineral deposits, and groundwater resources. By analyzing how sound waves travel through different materials, they can infer the composition and density of the earth's layers. This non-invasive approach allows for efficient resource management and environmental assessments without the need for extensive drilling or excavation.In medicine, sonic sounding is commonly associated with ultrasound technology. Ultrasound uses high-frequency sound waves to create images of internal organs, tissues, and even developing fetuses during pregnancy. This technique is invaluable for diagnosing medical conditions and monitoring health without exposing patients to harmful radiation. The ability of sonic sounding to provide real-time imaging has revolutionized prenatal care and various medical procedures, making it a cornerstone of modern diagnostic medicine.Furthermore, sonic sounding has applications in the field of architecture and engineering. It is employed to assess the integrity of structures, such as bridges and buildings, by detecting flaws or weaknesses within materials. Engineers can use sonic sounding to ensure that structures are safe and sound, ultimately protecting public safety and investment.Despite its many advantages, sonic sounding also faces challenges. For example, the accuracy of measurements can be affected by environmental factors such as temperature, pressure, and the presence of obstacles that may disrupt sound wave propagation. Additionally, researchers must consider the potential impact of sonic sounding on marine life, as excessive noise pollution can disrupt communication and navigation among aquatic species.In conclusion, sonic sounding is a versatile and powerful tool that has transformed various fields of study. Its applications range from mapping the depths of the ocean to diagnosing medical conditions and ensuring the safety of our infrastructure. As technology continues to advance, the potential for sonic sounding to provide even more insights into the world around us will undoubtedly expand, leading to further innovations and discoveries that benefit society as a whole.
在科学探索的领域中,术语声学探测指的是一种通过声波测量和分析材料及环境各种属性的方法。这项技术在海洋学、地质学甚至医学等领域中发挥了重要作用。通过利用声学探测技术,研究人员可以收集到重要的数据,这些数据在其他情况下将很难或不可能获得。例如,在海洋学中,声学探测用于绘制海底地图并研究水下特征,通过从船只发送声波并测量回声返回所需的时间。这些信息对于理解海洋生态系统、航行路线以及水下的地质构造至关重要。此外,声学探测在地球物理学领域也发挥着重要作用。科学家利用这种方法探索地下结构,包括石油和天然气储备、矿产资源和地下水资源。通过分析声波在不同材料中的传播方式,他们可以推断出地球层的成分和密度。这种非侵入性的方法使得资源管理和环境评估变得高效,无需进行广泛的钻探或挖掘。在医学中,声学探测通常与超声技术相关联。超声使用高频声波创建内部器官、组织甚至妊娠期间发育中的胎儿的图像。这项技术对于诊断医疗条件和监测健康非常宝贵,而不会使患者暴露于有害辐射中。声学探测提供实时成像的能力彻底改变了产前护理和各种医疗程序,使其成为现代诊断医学的基石。此外,声学探测在建筑和工程领域也有应用。它被用来评估结构的完整性,例如桥梁和建筑物,通过检测材料中的缺陷或弱点。工程师可以利用声学探测确保结构的安全性,从而最终保护公众安全和投资。尽管有许多优点,声学探测也面临挑战。例如,测量的准确性可能受到温度、压力和可能干扰声波传播的障碍物等环境因素的影响。此外,研究人员必须考虑声学探测对海洋生物的潜在影响,因为过度的噪音污染会干扰水生物种的交流和导航。总之,声学探测是一种多功能且强大的工具,改变了各个研究领域。它的应用范围从绘制海洋深度到诊断医疗条件以及确保基础设施的安全。随着技术的不断进步,声学探测提供更多洞察我们周围世界的潜力无疑将扩大,带来进一步的创新和发现,使整个社会受益。
相关单词
