gyrator

简明释义

英[dʒaɪˈreɪtə(r)]美[ˈdʒaɪəreɪtər]

n. 回转器

英英释义

单词用法

同义词

反义词

例句

1.The Gyrator-Capacitor model is first introduced to modeling two-phase integrating magnetics Voltage Regulator Module(VRM), which can deduce the corresponding self-inductance and mutual inductance.

文章首先利用回转器-电容模型对两相电压调整模块进行建模研究，并推导出具体的磁集成自感和互感表达式；

2.The Gyrator-Capacitor model is first introduced to modeling two-phase integrating magnetics Voltage Regulator Module(VRM), which can deduce the corresponding self-inductance and mutual inductance.

文章首先利用回转器-电容模型对两相电压调整模块进行建模研究，并推导出具体的磁集成自感和互感表达式；

3.The system constitution is simplified by using gyrator transmission network to realize the live conversion of voltage and frequency, thus greatly enhancing the upper output frequency.

该方法利用回转器构成传输网络实现变压变频，使系统结构简化，且输出频率上限大幅度提高。

4.Regarding to the difficult analysis of coupled flux and magnetic modeling, a novel circuit model of integrating magnetics is proposed using Gyrator-Capacitor approach.

针对磁集成磁路耦合和建模分析的难点，提出了一种基于回转器-电容模型的磁集成建模方法。

5.In this paper a scheme for improving the dynamic characteristic of an automatic regulation system by way of an addition of a gyrator circuit is presented.

本文提出了一种用回转器改善自动调节系统动态特性的方案。

6.The method is applicable for other operational-amplifier gyrator circuits, which proves itself useful to design and application.

同样的方法也适用于其他的回转器电路分析，可供回转器的设计及应用时参考。

7.The complementary function of the gyrator in the automatic regulation system has been analyzed theoretically in this paper.

文中从理论上分析了回转器应用于调节系统的意义和工作特性。

8.In this approach, magnetic paths are modeled by capacitive circuits and windings are represented by two-ports gyrator.

在回转器—电容模型中，磁路由容性电路来模拟，绕组由双端口的回转器来代替。

9.The principle and the practice of an oscillation circuit using a gyrator are discussed.

本文叙述应用回转器的振荡电路的原理与实践。

10.Finally, gyrator pressure cylinder was designed to enhance.

最后对回转器加压提升油缸进行了设计。

11.The engineer designed a new type of gyrator to improve circuit efficiency.

工程师设计了一种新型的旋转器以提高电路效率。

12.In RF circuits, a gyrator can simulate an inductor without using physical coils.

在射频电路中，旋转器可以在不使用物理线圈的情况下模拟电感。

13.The gyrator is often used in active filter designs.

旋转器常用于主动滤波器设计中。

14.By incorporating a gyrator, the team was able to reduce the size of the amplifier.

通过加入一个旋转器，团队能够减小放大器的体积。

15.The application of a gyrator in this circuit allows for better impedance matching.

在这个电路中应用旋转器可以实现更好的阻抗匹配。

作文

In the realm of electrical engineering, the concept of a gyrator is often introduced as a fascinating and essential component in various circuits. A gyrator is a two-port passive circuit element that can simulate an inductor without requiring a physical inductive coil. This characteristic makes it incredibly valuable in modern electronics, especially in integrated circuits where space and efficiency are paramount. The operation of a gyrator relies on the principles of magnetic coupling and feedback, allowing it to create an inductive effect using resistors and capacitors instead of traditional inductors. The functionality of a gyrator can be understood through its ability to convert voltage into current and vice versa, depending on the configuration of the circuit. When a voltage is applied across one port of the gyrator, it generates a proportional current at the other port, effectively emulating the behavior of an inductor. This property is particularly useful in applications such as RF (radio frequency) design, where compactness and performance are crucial. By replacing bulky inductors with a gyrator, engineers can design smaller and more efficient circuits that still deliver high performance. One of the most significant advantages of using a gyrator is its ability to provide a tunable inductance. By adjusting the values of the passive components in the circuit, designers can change the effective inductance of the gyrator dynamically. This flexibility allows for the creation of adaptive filters and oscillators that can respond to varying frequencies and signal conditions. Moreover, the use of a gyrator can lead to improved circuit stability and reduced power consumption, making it an attractive option for contemporary electronic devices. In addition to its practical applications, the gyrator also serves as a powerful theoretical tool in the analysis of complex circuits. It can simplify the modeling of certain systems, allowing engineers to focus on the essential elements of their designs without getting bogged down by the intricacies of traditional inductive components. This simplification not only speeds up the design process but also enhances the overall understanding of circuit behavior. Furthermore, with the advent of new technologies such as MEMS (Micro-Electro-Mechanical Systems), the gyrator has found its way into even smaller and more intricate devices. As technology continues to advance, the importance of components like the gyrator will only grow, paving the way for innovations in various fields, from telecommunications to consumer electronics. In conclusion, the gyrator stands out as a remarkable invention within the field of electrical engineering. Its ability to simulate inductance, offer tunable properties, and simplify circuit design underscores its significance in modern electronics. As engineers continue to push the boundaries of innovation, the gyrator will undoubtedly play a crucial role in shaping the future of electronic devices, making them more compact, efficient, and versatile than ever before.

在电气工程领域，gyrator的概念常常被引入作为各种电路中一种迷人且重要的组成部分。gyrator是一种两端口的无源电路元件，可以模拟电感，而无需物理电感线圈。这一特性使其在现代电子设备中极具价值，尤其是在集成电路中，空间和效率至关重要。gyrator的操作依赖于磁耦合和反馈原理，使其能够利用电阻器和电容器而不是传统电感器来产生电感效应。 gyrator的功能可以通过其将电压转化为电流及反之的能力来理解，具体取决于电路的配置。当在gyrator的一端施加电压时，它会在另一端产生与之成比例的电流，从而有效地模拟电感器的行为。这一特性在射频（RF）设计等应用中尤为有用，因为在这些应用中，小型化和性能至关重要。通过用gyrator替代笨重的电感器，工程师可以设计出更小、更高效的电路，同时仍然提供高性能。 使用gyrator的一个显著优势是其提供可调电感的能力。通过调整电路中无源元件的值，设计者可以动态改变gyrator的有效电感。这种灵活性允许创建自适应滤波器和振荡器，能够响应不同频率和信号条件。此外，使用gyrator还可以提高电路的稳定性并降低功耗，使其成为当代电子设备的一个吸引选项。 除了实际应用之外，gyrator还作为分析复杂电路的强大理论工具。它可以简化某些系统的建模，使工程师能够专注于设计的基本元素，而不必被传统电感元件的复杂性所困扰。这种简化不仅加速了设计过程，还增强了对电路行为的整体理解。 此外，随着MEMS（微电机械系统）等新技术的出现，gyrator也进入了更小、更复杂的设备中。随着技术的不断进步，像gyrator这样的组件的重要性只会增加，为电信、消费电子等各个领域的创新铺平道路。 总之，gyrator作为电气工程领域的一项杰出发明脱颖而出。它模拟电感、提供可调特性以及简化电路设计的能力突显了其在现代电子设备中的重要性。随着工程师不断推动创新的边界，gyrator无疑将在塑造电子设备的未来中发挥关键作用，使其比以往任何时候都更加紧凑、高效和多功能。