effective conductance

简明释义

有效电导

英英释义

例句

1.The effective conductance 有效导电性 of the electrolyte in a battery affects its overall efficiency.

电池中电解质的有效导电性 有效导电性影响其整体效率。

2.In a parallel resistor network, the effective conductance 有效导电性 can be calculated by summing the conductances of individual resistors.

在并联电阻网络中，有效导电性 有效导电性可以通过将各个电阻的导电性相加来计算。

3.The circuit design must account for the effective conductance 有效导电性 of each component to ensure optimal performance.

电路设计必须考虑每个组件的有效导电性 有效导电性，以确保最佳性能。

4.Engineers often test the effective conductance 有效导电性 of various alloys to find the best option for wiring.

工程师们常常测试各种合金的有效导电性 有效导电性以找到最佳的布线选项。

5.The effective conductance 有效导电性 of the material determines how well it can carry an electric current.

材料的有效导电性 有效导电性决定了它能多好地传导电流。

作文

In the realm of electrical engineering, the concept of effective conductance plays a crucial role in understanding how electrical circuits function. Effective conductance refers to the ability of a circuit or component to conduct electric current effectively under specific conditions. This measurement takes into account various factors, including the physical properties of the materials involved, the temperature, and the frequency of the applied voltage. To elaborate further, consider a simple circuit consisting of resistors connected in series and parallel. The total conductance of such a network can be calculated by analyzing the individual conductances of each resistor. In this context, effective conductance is particularly important because it allows engineers to predict how the circuit will behave when subjected to different electrical loads. For instance, if one resistor in a parallel configuration fails, the effective conductance of the entire circuit changes, which can lead to unexpected results such as increased current through the remaining resistors. Moreover, the concept of effective conductance is not limited to just resistive components. It also applies to capacitors and inductors, where the reactance can significantly affect the overall conductance of the circuit. Understanding how these components interact allows engineers to design more efficient circuits that minimize energy loss and improve performance. For example, in high-frequency applications, the effective conductance of a circuit may vary due to skin effect, where the current tends to flow near the surface of conductors. This phenomenon must be taken into account when designing RF circuits to ensure optimal signal integrity. Additionally, effective conductance is a vital parameter in the field of materials science. Researchers often investigate the effective conductance of various materials to determine their suitability for specific applications, such as in the development of semiconductors or superconductors. By measuring how well a material can conduct electricity, scientists can gain insights into its atomic structure and electronic properties, which are essential for advancing technology in electronics and energy storage. In conclusion, the term effective conductance encompasses a wide range of applications and implications in electrical engineering and materials science. Its significance lies not only in circuit design and analysis but also in the broader context of technological advancement. As we continue to explore new materials and improve existing technologies, a deep understanding of effective conductance will be paramount in driving innovation and efficiency in electrical systems. Engineers and scientists alike must remain vigilant in their study of this concept to harness its full potential for future advancements in the field. In summary, effective conductance (有效电导) is a fundamental concept that helps us understand how electrical systems operate and interact with various components. It is essential for engineers and researchers to grasp this idea to design better circuits and develop new materials that can improve our technological landscape.

在电气工程领域，“有效电导”的概念在理解电路如何运作方面发挥着至关重要的作用。有效电导是指电路或组件在特定条件下有效传导电流的能力。这一测量考虑了多个因素，包括所涉及材料的物理特性、温度和施加电压的频率。进一步阐述，考虑一个由串联和并联连接的电阻器组成的简单电路。可以通过分析每个电阻器的单独电导来计算该网络的总电导。在这种情况下，有效电导尤其重要，因为它允许工程师预测电路在不同电负载下的行为。例如，如果并联配置中的一个电阻器失效，则整个电路的有效电导会发生变化，这可能导致意想不到的结果，如其余电阻器中的电流增加。此外，有效电导的概念不仅限于电阻组件。它还适用于电容器和电感器，其中反应性可能会显著影响电路的整体电导。了解这些组件如何相互作用使工程师能够设计出更高效的电路，最大限度地减少能量损失，提高性能。例如，在高频应用中，由于表皮效应，电路的有效电导可能会变化，此时电流倾向于流向导体的表面。在设计射频电路时，必须考虑这一现象，以确保最佳信号完整性。此外，有效电导是材料科学领域的重要参数。研究人员经常研究各种材料的有效电导以确定其在特定应用中的适用性，例如在半导体或超导体的开发中。通过测量材料传导电流的能力，科学家可以深入了解其原子结构和电子特性，这对于推动电子和能源存储技术的发展至关重要。总之，术语有效电导涵盖了电气工程和材料科学中广泛的应用和影响。它的重要性不仅体现在电路设计和分析中，还体现在更广泛的技术进步背景下。随着我们继续探索新材料并改善现有技术，对有效电导的深入理解将对推动电气系统的创新和效率至关重要。工程师和科学家都必须保持对这一概念的关注，以充分利用其在未来发展中的潜力。总而言之，有效电导（有效电导）是一个基本概念，有助于我们理解电气系统如何运作以及如何与各种组件相互作用。工程师和研究人员掌握这一理念对于设计更好的电路和开发能够改善我们技术环境的新材料至关重要。