probe coupling

简明释义

探针耦合

英英释义

例句

1.Proper alignment of the instruments is crucial for effective probe coupling.

仪器的正确对齐对有效的探头耦合至关重要。

2.The technician explained how the probe coupling affects the accuracy of the measurements.

技术员解释了探头耦合如何影响测量的准确性。

3.The scientist adjusted the settings of the device to optimize the probe coupling for better signal reception.

科学家调整了设备的设置，以优化探头耦合以获得更好的信号接收。

4.In this experiment, we need to ensure that the probe coupling is strong enough to detect small variations.

在这个实验中，我们需要确保探头耦合足够强，以检测微小的变化。

5.We observed a significant improvement in data quality after enhancing the probe coupling mechanism.

在增强探头耦合机制后，我们观察到数据质量显著提高。

作文

In the realm of physics and engineering, the term probe coupling refers to the interaction between a measuring instrument or sensor (the probe) and the system being measured. This concept is crucial in various applications, including telecommunications, material science, and biomedical engineering. Understanding probe coupling is essential for improving measurement accuracy and ensuring reliable data acquisition.To elaborate, probe coupling can be seen as the bridge that connects the sensor to the physical phenomenon it aims to measure. For instance, in telecommunications, probes are used to monitor signals transmitted over networks. The efficiency of these probes depends significantly on their coupling with the electromagnetic fields present in the environment. If the coupling is poor, the measurements will be inaccurate, leading to potential failures in communication systems.In material science, probe coupling plays a vital role in techniques such as scanning tunneling microscopy (STM) and atomic force microscopy (AFM). These methods rely on the precise interaction between the probe and the surface of the material being studied. A strong probe coupling ensures that the probe can effectively sense the forces at play, providing high-resolution images and detailed information about the material's properties.Moreover, in the field of biomedical engineering, probe coupling is critical when designing sensors that monitor physiological parameters, such as blood pressure or glucose levels. The probe must couple well with the biological tissues to obtain accurate readings. If the coupling is suboptimal, it may lead to erroneous data, which could adversely affect patient care.The significance of probe coupling extends beyond just measurement accuracy; it also influences the design and functionality of the probes themselves. Engineers and scientists must consider various factors, such as the materials used, the geometry of the probe, and the frequency of operation, to optimize the coupling effect. For example, in wireless systems, the alignment of antennas can greatly affect the probe coupling, impacting signal strength and quality.Furthermore, advancements in technology have introduced new methods to enhance probe coupling. Innovations such as nanotechnology and advanced materials allow for the development of more sensitive and efficient probes. By leveraging these technologies, researchers can achieve better performance in their measurements, ultimately leading to advancements in their respective fields.In conclusion, probe coupling is a fundamental concept that underlies many scientific and engineering disciplines. Its importance cannot be overstated, as it directly affects the accuracy and reliability of measurements taken by various probes. As technology continues to evolve, understanding and optimizing probe coupling will remain a key focus for researchers and engineers alike, paving the way for new discoveries and innovations in measurement techniques. By mastering this concept, professionals can ensure that their work contributes effectively to the advancement of knowledge and technology in their fields.

在物理和工程领域，术语探针耦合指的是测量仪器或传感器（探针）与被测系统之间的相互作用。这个概念在电信、材料科学和生物医学工程等多个应用中至关重要。理解探针耦合对于提高测量精度和确保可靠的数据采集至关重要。进一步阐述，探针耦合可以看作是连接传感器与其旨在测量的物理现象之间的桥梁。例如，在电信中，探针用于监测网络上传输的信号。这些探针的效率在很大程度上取决于它们与环境中存在的电磁场的耦合。如果耦合不良，测量将不准确，导致通信系统可能出现故障。在材料科学中，探针耦合在扫描隧道显微镜（STM）和原子力显微镜（AFM）等技术中起着至关重要的作用。这些方法依赖于探针与被研究材料表面之间的精确相互作用。强的探针耦合确保探针能够有效地感知所涉及的力，从而提供高分辨率的图像和关于材料特性的详细信息。此外，在生物医学工程领域，探针耦合在设计监测生理参数（如血压或葡萄糖水平）的传感器时至关重要。探针必须与生物组织良好耦合，以获得准确的读数。如果耦合不理想，可能会导致错误的数据，从而对患者护理产生不利影响。探针耦合的重要性不仅仅体现在测量精度上；它还影响着探针本身的设计和功能。工程师和科学家必须考虑多种因素，例如所用材料、探针的几何形状和操作频率，以优化耦合效果。例如，在无线系统中，天线的对齐可以极大地影响探针耦合，从而影响信号强度和质量。此外，技术的进步引入了增强探针耦合的新方法。纳米技术和先进材料等创新使得开发出更灵敏、更高效的探针成为可能。通过利用这些技术，研究人员可以在其测量中实现更好的性能，最终推动各自领域的进步。总之，探针耦合是许多科学和工程学科的基本概念。它的重要性不容小觑，因为它直接影响各种探针进行测量的准确性和可靠性。随着技术的不断发展，理解和优化探针耦合将始终是研究人员和工程师的重点，开辟新的发现和测量技术的创新之路。通过掌握这一概念，专业人士可以确保他们的工作有效地为其领域的知识和技术进步做出贡献。