amplitude permeability

简明释义

振幅磁导率;

英英释义

例句

1.Engineers need to consider amplitude permeability when designing filtration systems.

工程师在设计过滤系统时需要考虑幅度渗透性。

2.The study focused on the effects of amplitude permeability on fluid flow in porous media.

这项研究集中于幅度渗透性对多孔介质中流体流动的影响。

3.In geophysics, amplitude permeability helps predict the behavior of subsurface fluids.

在地球物理学中，幅度渗透性有助于预测地下流体的行为。

4.To improve water retention, farmers should analyze the amplitude permeability of their soil.

为了改善水分保持，农民应该分析他们土壤的幅度渗透性。

5.The research indicated a strong correlation between soil composition and amplitude permeability.

研究表明土壤成分与幅度渗透性之间存在强相关性。

作文

In the realm of physics and engineering, various concepts play a crucial role in understanding the behavior of materials and their interactions with forces. One such concept is amplitude permeability, which refers to the ability of a material to allow the passage of waves or signals through it, particularly in relation to its amplitude. This property is essential in fields such as telecommunications, acoustics, and even medical imaging, where the transmission of waves can significantly affect the quality and clarity of the information received.To comprehend amplitude permeability, we must first explore what is meant by 'amplitude.' Amplitude is a measure of the maximum extent of a vibration or oscillation, often represented as the height of a wave from its mean position. In many applications, the amplitude of a wave can determine how effectively it transmits energy or information. For instance, in audio engineering, the amplitude of sound waves can affect loudness, while in electromagnetic waves, it can influence signal strength.Permeability, on the other hand, generally describes how easily a substance can be penetrated by another substance. In the context of amplitude permeability, it specifically pertains to how well a medium can transmit waves based on their amplitude. This concept is particularly relevant in materials science, where different materials exhibit varying degrees of permeability. For example, some materials may allow high-amplitude waves to pass through with minimal attenuation, while others may absorb or reflect these waves, diminishing their amplitude and altering the information they carry.The significance of amplitude permeability becomes evident when considering its applications. In telecommunications, for instance, the ability of cables to maintain signal integrity over long distances relies heavily on their amplitude permeability. Cables that possess high amplitude permeability can transmit signals without significant loss of amplitude, ensuring that the information reaches its destination accurately. This is vital for maintaining clear communication in our increasingly connected world.Similarly, in the field of acoustics, understanding amplitude permeability can lead to better designs for concert halls or recording studios. By selecting materials with appropriate amplitude permeability, architects and sound engineers can enhance sound quality, ensuring that music and speech are transmitted clearly without distortion. This consideration is crucial for creating environments where auditory experiences are optimized.In medical imaging, such as ultrasound, amplitude permeability also plays a fundamental role. The effectiveness of ultrasound waves in producing clear images of internal organs depends on the amplitude permeability of the tissues being examined. Different tissues have varying levels of permeability, which can affect the amplitude of the returning waves. Understanding this property allows healthcare professionals to interpret images accurately and diagnose conditions more effectively.In conclusion, amplitude permeability is a multifaceted concept that bridges various scientific disciplines. Its implications stretch from telecommunications to acoustics and medical imaging, highlighting the importance of wave behavior in practical applications. By grasping the nuances of amplitude permeability, we can better understand how materials interact with waves, leading to advancements in technology and improved outcomes in various fields. As research continues to evolve, the exploration of amplitude permeability will undoubtedly yield further insights into the complex relationships between materials and waves, paving the way for innovative solutions to modern challenges.

在物理和工程领域，各种概念在理解材料的行为及其与力的相互作用方面发挥着至关重要的作用。其中一个概念是幅度渗透率，它指的是材料允许波或信号通过的能力，特别是与其幅度相关的特性。这个属性在电信、声学甚至医学成像等领域至关重要，在这些领域，波的传输可以显著影响接收到的信息的质量和清晰度。要理解幅度渗透率，我们首先必须探讨“幅度”所指的含义。幅度是振动或振荡最大程度的量度，通常表示为波从其平均位置的高度。在许多应用中，波的幅度可以决定其传递能量或信息的有效性。例如，在音频工程中，声波的幅度可以影响响度，而在电磁波中，它可以影响信号强度。另一方面，渗透率通常描述一种物质被另一种物质穿透的容易程度。在幅度渗透率的背景下，它特别涉及到介质根据其幅度传输波的能力。这个概念在材料科学中尤为相关，不同的材料表现出不同程度的渗透率。例如，有些材料可能允许高幅度的波以最小的衰减通过，而其他材料可能吸收或反射这些波，从而降低其幅度并改变其携带的信息。当考虑其应用时，幅度渗透率的重要性变得显而易见。在电信领域，例如，电缆保持长距离信号完整性的能力在很大程度上依赖于它们的幅度渗透率。具有高幅度渗透率的电缆可以在没有显著幅度损失的情况下传输信号，确保信息准确到达目的地。这对于在我们日益互联的世界中保持清晰的通信至关重要。同样，在声学领域，理解幅度渗透率可以导致音乐厅或录音室的更好设计。通过选择具有适当幅度渗透率的材料，建筑师和声学工程师可以增强声音质量，确保音乐和演讲清晰传输而没有失真。这种考虑对于创造优化听觉体验的环境至关重要。在医学成像中，例如超声波，幅度渗透率也发挥着根本作用。超声波在产生内部器官清晰图像方面的有效性取决于被检查组织的幅度渗透率。不同的组织具有不同的渗透率，这会影响返回波的幅度。理解这个属性使医疗专业人员能够准确解读图像，更有效地诊断病症。总之，幅度渗透率是一个多面向的概念，跨越各种科学学科。它的影响从电信到声学再到医学成像，突显了波行为在实际应用中的重要性。通过掌握幅度渗透率的细微差别，我们可以更好地理解材料如何与波相互作用，从而推动技术进步和改善各个领域的结果。随着研究的不断发展，对幅度渗透率的探索无疑会为材料与波之间复杂关系的进一步洞察铺平道路，为现代挑战提供创新解决方案。