antiresonance frequency

简明释义

电流谐振频率

英英释义

例句

1.During the testing phase, we identified the antiresonance frequency 反共振频率 which helped us improve the overall design.

在测试阶段，我们识别了 antiresonance frequency 反共振频率，这帮助我们改进了整体设计。

2.In vibration analysis, engineers often look for the antiresonance frequency 反共振频率 to minimize unwanted vibrations in machinery.

在振动分析中，工程师通常寻找 antiresonance frequency 反共振频率 以最小化机械中的不必要振动。

3.The antiresonance frequency 反共振频率 is critical in the tuning of acoustic devices to ensure optimal sound quality.

在声学设备的调谐中，antiresonance frequency 反共振频率 是确保最佳音质的关键。

4.The suspension system of the vehicle was designed to avoid the antiresonance frequency 反共振频率 that could lead to instability.

车辆的悬挂系统设计旨在避免可能导致不稳定的 antiresonance frequency 反共振频率。

5.Engineers use simulations to predict the antiresonance frequency 反共振频率 of new materials before they are manufactured.

工程师在新材料制造之前使用模拟来预测 antiresonance frequency 反共振频率。

作文

In the realm of physics and engineering, the concept of antiresonance frequency plays a pivotal role in understanding how systems respond to various frequencies of excitation. The term antiresonance frequency refers to a specific frequency at which a system exhibits minimal response or vibration when subjected to external forces. This phenomenon is particularly significant in the design and analysis of mechanical structures, electronic circuits, and even in the field of acoustics.To comprehend the importance of antiresonance frequency, one must first grasp the principle of resonance. Resonance occurs when a system is driven at its natural frequency, leading to amplified oscillations. For example, a swing moves higher when pushed at just the right moment, which is akin to a resonant frequency. However, the opposite effect can be observed at the antiresonance frequency. At this frequency, the energy input into the system does not result in significant oscillation, effectively minimizing the system's response.This property is highly beneficial in various applications. In engineering, designers often seek to identify the antiresonance frequency of structures to prevent excessive vibrations that could lead to failure. For instance, in the construction of bridges or buildings, ensuring that the antiresonance frequency does not coincide with the frequencies generated by wind or seismic activity is crucial. By doing so, engineers can enhance the durability and safety of these structures.Moreover, in the field of electronics, the concept of antiresonance frequency is utilized in filter design. Filters are essential components in communication systems, allowing certain frequencies to pass while attenuating others. By incorporating elements that exploit the antiresonance frequency, engineers can create filters that effectively eliminate unwanted signals, thereby improving the clarity and quality of transmitted information.Acoustics also benefits from the understanding of antiresonance frequency. In soundproofing and audio engineering, knowing the antiresonance frequency of materials can help in designing spaces that minimize sound transmission. For instance, certain materials may absorb sound waves at their antiresonance frequency, making them ideal for use in concert halls or recording studios where sound quality is paramount.In conclusion, the antiresonance frequency is a fundamental concept that underscores the behavior of various systems under external excitations. Its significance spans across multiple disciplines, including mechanical engineering, electronics, and acoustics. By understanding and utilizing the principles of antiresonance frequency, scientists and engineers can design more effective and safer systems. As technology continues to advance, the exploration of antiresonance frequency will undoubtedly lead to innovative solutions and improved designs in numerous fields.

在物理和工程领域，抗共振频率的概念在理解系统如何响应各种激励频率方面发挥着关键作用。术语抗共振频率指的是在受到外部力作用时，系统表现出最小响应或振动的特定频率。这种现象在机械结构、电子电路甚至声学领域的设计和分析中尤为重要。要理解抗共振频率的重要性，首先必须掌握共振的原理。当系统在其自然频率下被驱动时，会导致振荡的放大，这就是共振。例如，当在适当的时刻推动秋千时，秋千会摆得更高，这类似于共振频率。然而，在抗共振频率下可以观察到相反的效果。在这个频率下，输入到系统中的能量不会导致显著的振荡，从而有效地最小化系统的响应。这一特性在各种应用中非常有益。在工程学中，设计师通常寻求识别结构的抗共振频率，以防止可能导致故障的过度振动。例如，在桥梁或建筑物的建设中，确保抗共振频率与风或地震活动产生的频率不重合至关重要。通过这样做，工程师可以增强这些结构的耐久性和安全性。此外，在电子领域，抗共振频率的概念被用于滤波器设计。滤波器是通信系统中的重要组件，允许某些频率通过，同时衰减其他频率。通过结合利用抗共振频率的元件，工程师可以创建有效消除不必要信号的滤波器，从而改善传输信息的清晰度和质量。声学也受益于对抗共振频率的理解。在隔音和音频工程中，了解材料的抗共振频率可以帮助设计最小化声音传播的空间。例如，某些材料可能在其抗共振频率下吸收声波，使它们成为音乐厅或录音室等对声音质量要求极高的场所的理想选择。总之，抗共振频率是一个基本概念，强调了各种系统在外部激励下的行为。它的重要性跨越多个学科，包括机械工程、电子学和声学。通过理解和利用抗共振频率的原理，科学家和工程师可以设计出更有效和更安全的系统。随着技术的不断进步，对抗共振频率的探索无疑将引领各个领域的创新解决方案和改进设计。