distributed inductance

简明释义

分布电感

英英释义

例句

1.To minimize losses, it's essential to understand how distributed inductance 分布电感 affects power distribution networks.

为了最小化损耗，了解 分布电感 distributed inductance 如何影响电力分配网络是至关重要的。

2.The distributed inductance 分布电感 in transmission lines can lead to unexpected resonance effects.

传输线中的 分布电感 distributed inductance 可能导致意想不到的共振效应。

3.Engineers must account for distributed inductance 分布电感 when designing printed circuit boards.

工程师在设计印刷电路板时必须考虑到 分布电感 distributed inductance。

4.In high-frequency circuits, the effect of distributed inductance 分布电感 can significantly impact signal integrity.

在高频电路中，分布电感 distributed inductance 的影响可以显著影响信号完整性。

5.The calculation of distributed inductance 分布电感 is crucial for ensuring proper impedance matching.

计算 分布电感 distributed inductance 对于确保适当的阻抗匹配至关重要。

作文

In the field of electrical engineering, the concept of distributed inductance plays a crucial role in understanding how electrical energy is stored and transferred in various components. To grasp the significance of distributed inductance (分布电感), it is essential to comprehend its definition and application in real-world scenarios. Distributed inductance refers to the phenomenon where inductance is not concentrated in a single point or component but rather spread over a length of conductor or circuit. This is particularly important in high-frequency applications, where the physical dimensions of the components become comparable to the wavelength of the signals being transmitted. In such cases, the inductance is no longer just a simple lumped parameter but needs to be treated as a distributed element. For instance, consider a long transmission line used for communication purposes. The inductance associated with this line is not merely a function of its total length but varies along its length. Each segment of the line contributes to the overall inductance, leading to a more complex interaction with capacitance and resistance. This is where the concept of distributed inductance becomes vital. Engineers must account for this distribution when designing circuits to ensure signal integrity and minimize losses. The mathematical representation of distributed inductance can be described using transmission line theory, which involves parameters like the series inductance per unit length. By modeling the transmission line as a series of small segments, each with its own inductance, engineers can analyze the behavior of the entire line under various conditions. This approach allows for a more accurate prediction of how signals will propagate through the line, taking into account factors such as reflections and attenuation. Moreover, distributed inductance is not limited to transmission lines. It is also relevant in the design of inductors, transformers, and other electromagnetic devices. For example, in a coil, the wire’s length and arrangement influence the inductance experienced by the current flowing through it. As the frequency increases, the effects of distributed inductance become more pronounced, necessitating careful consideration during the design phase. In practical applications, engineers often use simulation tools to model distributed inductance and its effects on circuit performance. These simulations help in identifying potential issues before physical prototypes are built, saving both time and resources. Additionally, understanding distributed inductance aids in optimizing designs for better efficiency and performance, particularly in high-speed digital circuits and RF applications. In conclusion, the concept of distributed inductance (分布电感) is fundamental in electrical engineering, especially in high-frequency applications. It highlights the importance of considering inductance as a distributed property rather than a lumped one. By acknowledging the variations in inductance along a conductor, engineers can design more effective and reliable electronic systems. As technology continues to advance, the relevance of distributed inductance will only grow, making it an essential topic for both current and future engineers to master.

在电气工程领域，分布电感的概念在理解电能如何在各种组件中存储和传输方面发挥着至关重要的作用。要掌握分布电感的意义，首先需要理解它的定义及其在现实场景中的应用。分布电感是指电感不是集中在单一的点或组件上，而是分布在导体或电路的长度上。这在高频应用中尤其重要，因为组件的物理尺寸变得与所传输信号的波长相当。在这种情况下，电感不再只是一个简单的集中参数，而需要被视为一个分布式元件。例如，考虑用于通信目的的长传输线。与这条线相关的电感不仅仅是其总长度的函数，而是沿其长度变化。线路的每个段都对整体电感产生贡献，导致与电容和电阻之间的更复杂的相互作用。这就是分布电感概念变得至关重要的地方。工程师必须在设计电路时考虑这一分布，以确保信号完整性并最小化损耗。分布电感的数学表示可以通过传输线理论来描述，该理论涉及单位长度的串联电感等参数。通过将传输线建模为一系列小段，每段都有自己的电感，工程师可以分析整个线路在不同条件下的行为。这种方法允许更准确地预测信号如何通过线路传播，同时考虑反射和衰减等因素。此外，分布电感并不限于传输线。它在电感器、变压器和其他电磁设备的设计中也很相关。例如，在一个线圈中，导线的长度和排列会影响流经它的电流所经历的电感。随着频率的增加，分布电感的影响变得更加明显，因此在设计阶段需要仔细考虑。在实际应用中，工程师通常使用仿真工具来模拟分布电感及其对电路性能的影响。这些仿真帮助识别潜在问题，避免在物理原型构建之前浪费时间和资源。此外，理解分布电感有助于优化设计，以提高效率和性能，特别是在高速数字电路和射频应用中。总之，分布电感（分布电感）的概念在电气工程中是基础性的，尤其是在高频应用中。它强调了将电感视为分布特性而非集中特性的必要性。通过承认导体沿线的电感变化，工程师可以设计出更有效和可靠的电子系统。随着技术的不断进步，分布电感的相关性只会增加，使其成为当前和未来工程师必须掌握的基本主题。