susceptance

简明释义

英[səˈseptəns]美[səˈseptəns]

n. [电] 电纳

英英释义

单词用法

同义词

反义词

例句

1.Zero reactance; Infinite reactance; Zero reactance - Infinite susceptance; Infinite reactance - Zero susceptance.

零阻抗；无穷大阻抗；零阻抗-无穷大电纳；无穷大阻抗-零电纳。

2.The robot can complete water temperature, depth and acoustic susceptance detection, water imaging and other works and has the advantages of light weight, flexibility, reliable work and the like.

该水下机器人可以完成水体的温度、深度、声纳、及水体摄像等工作，具有轻便灵活、工作可靠等优点。

3.The robot can complete water temperature, depth and acoustic susceptance detection, water imaging and other works and has the advantages of light weight, flexibility, reliable work and the like.

该水下机器人可以完成水体的温度、深度、声纳、及水体摄像等工作，具有轻便灵活、工作可靠等优点。

4.Then, an efficient method for upgrading the reversibility of full bus admittance matrix of a distribution network is proposed by perturbing shunt susceptance.

提出了一种基于节点电纳摄动改造配电网全节点导纳矩阵可逆性的方法。

5.In electrical engineering, the concept of susceptance is crucial for analyzing AC circuits.

在电气工程中，susceptance的概念对于分析交流电路至关重要。

6.The total susceptance of the circuit can be calculated by summing the individual susceptances of all components.

电路的总susceptance可以通过将所有组件的个体susceptance相加来计算。

7.Understanding susceptance is essential for optimizing the performance of RF circuits.

理解susceptance对于优化射频电路的性能至关重要。

8.The susceptance value helps in designing filters for signal processing applications.

susceptance值有助于为信号处理应用设计滤波器。

9.Engineers often use susceptance to determine the reactive power in a system.

工程师通常使用susceptance来确定系统中的无功功率。

作文

In the realm of electrical engineering, understanding various concepts is crucial for designing effective circuits. One such concept is susceptance, which plays a significant role in the analysis of alternating current (AC) circuits. Susceptance refers to the measure of how easily a circuit allows the flow of alternating current, in relation to voltage. It is the reciprocal of reactance, which is the opposition that inductors and capacitors present to a change in current. This means that while reactance can impede the flow of current, susceptance indicates how readily that current can pass through a circuit component. To further elaborate, susceptance is expressed in siemens (S), and it can be calculated using the formula: B = 1/X, where B represents susceptance and X represents reactance. The concept of susceptance is particularly important when dealing with capacitive and inductive components in AC circuits. For instance, capacitors have positive susceptance, meaning they allow current to flow easily, while inductors have negative susceptance, indicating they resist the flow of current. Understanding susceptance is vital for engineers and technicians who work with AC systems because it helps them to predict how different components will interact within a circuit. For example, in power systems, managing susceptance can help improve the overall efficiency of energy transmission. By balancing the susceptance and reactance in a circuit, engineers can reduce losses and enhance performance. This balancing act is often referred to as power factor correction, which aims to minimize the difference between the voltage and current waveforms in an AC system. Moreover, susceptance also has implications in telecommunications and signal processing. In these fields, understanding how signals propagate through various media is essential. The susceptance of a transmission line, for example, can affect signal integrity and quality. Engineers must consider susceptance when designing filters and other components to ensure that signals are transmitted without distortion. In conclusion, the concept of susceptance is integral to the field of electrical engineering, influencing everything from circuit design to energy efficiency. By grasping the principles of susceptance, professionals can create more effective systems that optimize the flow of alternating current. As technology continues to advance, the importance of understanding such concepts will only grow, making it essential for future engineers to master the intricacies of susceptance and its applications in modern electrical systems.

在电气工程领域，理解各种概念对于设计有效的电路至关重要。其中一个概念是susceptance，它在交流电（AC）电路分析中发挥着重要作用。Susceptance指的是电路在电压的关系下，允许交流电流流动的容易程度。它是电抗的倒数，电抗是电感器和电容器对电流变化所产生的阻碍。这意味着，虽然电抗会阻碍电流的流动，但susceptance则表示电流流经电路元件的容易程度。进一步阐述，susceptance以西门子（S）为单位，可以使用公式B = 1/X进行计算，其中B代表susceptance，X代表电抗。Susceptance的概念在处理交流电路中的电容和电感元件时尤为重要。例如，电容器具有正的susceptance，这意味着它们允许电流轻松流动，而电感器则具有负的susceptance，表明它们抵制电流的流动。理解susceptance对于从事交流系统工作的工程师和技术人员至关重要，因为它帮助他们预测不同组件在电路中的相互作用。例如，在电力系统中，管理susceptance可以帮助提高能源传输的整体效率。通过平衡电路中的susceptance和电抗，工程师可以减少损失并提高性能。这种平衡行为通常被称为功率因数校正，旨在最小化交流系统中电压和电流波形之间的差异。此外，susceptance在电信和信号处理领域也具有重要意义。在这些领域，理解信号如何通过各种介质传播至关重要。例如，传输线的susceptance可能会影响信号的完整性和质量。工程师在设计滤波器和其他组件时必须考虑susceptance，以确保信号不失真地传输。总之，susceptance的概念在电气工程领域中是不可或缺的，影响着从电路设计到能源效率的方方面面。通过掌握susceptance的原理，专业人士可以创建更有效的系统，优化交流电流的流动。随着技术的不断进步，理解这样的概念的重要性只会增加，因此未来的工程师必须掌握susceptance及其在现代电气系统中的应用的复杂性。