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Parallel Resonance01:23

Parallel Resonance

188
The parallel RLC circuit is an arrangement where the resistor (R), inductor (L), and capacitor (C) are all connected to the same nodes and, as a result, share the same voltage across them. The parallel RLC circuit is analyzed in terms of admittance (Y), which reflects the ease with which current can flow. The admittance is given by:
188
Series Resonance01:17

Series Resonance

152
The RLC circuit impedance is defined as the ratio of the supply voltage to the circuit current. Resonance in such a circuit occurs when the imaginary part of this impedance equals zero. This specific condition means that the inductive reactance is exactly equal to the capacitive reactance. The frequency at which this happens is known as the resonant frequency. Mathematically, the resonant frequency is inversely proportional to the square root of the product of the inductance (L) and capacitance...
152
Characteristics of Series Resonant Circuit01:24

Characteristics of Series Resonant Circuit

230
Series resonance occurs in a circuit containing inductive (L), capacitive (C), and resistive (R) elements connected sequentially. At the resonance frequency, the inductive and capacitive reactances are equal in magnitude but opposite in sign, effectively canceling each other. This causes the circuit's impedance is minimal, primarily determined by the resistance R. The resonant frequency of an RLC circuit is defined as:
230
Design Example: Underdamped Parallel RLC Circuit01:17

Design Example: Underdamped Parallel RLC Circuit

270
Consider designing an oscillator circuit, a crucial component in various electronic devices and systems. The objective is to create an oscillator circuit with specific characteristics: a damped natural frequency of 4 kHz and a damping factor of 4 radians per second. To accomplish this, a parallel RLC circuit is employed, known for its ability to sustain oscillations at a resonant frequency. In this case, the damping factor is pivotal in achieving the desired performance.
Starting with a fixed...
270
Resonance in an AC Circuit01:26

Resonance in an AC Circuit

2.0K
The property of an inductor makes it resist any change in the current passing through it, while the property of a capacitor is to build up the charge across its terminals. Hence, if an inductor and capacitor are connected in series, they have opposite effects on the relative phase between current and voltage. The current through the circuit undergoes forced oscillation at the frequency of the source. The resistance term in an R-L-C circuit acts as a damping term because power is dissipated...
2.0K
Concept of Resonance and its Characteristics01:19

Concept of Resonance and its Characteristics

5.0K
If a driven oscillator needs to resonate at a specific frequency, then very light damping is required. An example of light damping includes playing piano strings and many other musical instruments. Conversely, to achieve small-amplitude oscillations as in a car's suspension system, heavy damping is required. Heavy damping reduces the amplitude, but the tradeoff is that the system responds at more frequencies. Speed bumps and gravel roads prove that even a car's suspension system is not...
5.0K

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  1. 首页
  2. 有效的微共振器频率.
  1. 首页
  2. 有效的微共振器频率.

相关实验视频

Microwave Photonics Systems Based on Whispering-gallery-mode Resonators
12:18

Microwave Photonics Systems Based on Whispering-gallery-mode Resonators

Published on: August 5, 2013

16.9K

有效的微共振器频率.

Qi-Fan Yang1, Yaowen Hu1,2, Victor Torres-Company3

  • 1State Key Laboratory for Artificial Microstructure and Mesoscopic Physics and Frontiers Science Center for Nano-optoelectronics, School of Physics, Peking University, Beijing, China.

eLight
|October 17, 2024

在PubMed 上查看摘要

概括
此摘要是机器生成的。

芯片级光学频率 (微) 现在提供高效率,超过50%的能量转换. 微共振器非线性光学和超低损耗光子电路的进步使实验室之外的强大功能成为可能.

关键词:
非线性光子学是一种非线性光子学.一个光学频率.光学微共振器是一种光学微共振器.

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Generation and Coherent Control of Pulsed Quantum Frequency Combs
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Generation and Coherent Control of Pulsed Quantum Frequency Combs

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科学领域:

  • 光子学和光学工程的工程.
  • 非线性光学是非线性光学.
  • 综合光子学 综合光子学

背景情况:

  • 光学频率已经从实验室设置过渡到芯片规模平台.
  • 微振器是产生具有大小,重量和功率优势的子的关键.
  • 了解增益/损失动态和超低损失电路对于效率至关重要.

研究的目的:

  • 审查最近微型效率方面的进展.
  • 为了突出新的光子设备和送策略.
  • 讨论微型的集成到实际应用中.

主要方法:

  • 总结非线性微共振器光学方面的进展.
  • 分析超低损耗光子电路的发展.
  • 审查用于生产的新送技术.

主要成果:

  • 微型电池的能量转换效率已经超过50%.
  • 显著的改进源于增强的非线性过程和优化的光子电路.
  • 这些进步为实用,高性能应用铺平了道路.

结论:

  • 微型技术已经实现了主要的效率里程碑.
  • 这些发展使功能进一步集成成为可能.
  • 在该领域的剩余挑战被确定为未来的研究.