frequency maximum utilizable
简明释义
最高可用频率
英英释义
The highest level of frequency that can be effectively used or utilized in a given context, such as in communication systems or signal processing. | 在特定情况下(如通信系统或信号处理)可以有效使用或利用的最高频率水平。 |
例句
1.In telecommunications, understanding the frequency maximum utilizable is crucial for efficient signal transmission.
在电信领域,理解可利用的最大频率对高效信号传输至关重要。
2.The software was designed to analyze the frequency maximum utilizable for different frequencies in real-time.
该软件被设计用于实时分析不同频率的可利用的最大频率。
3.The engineer calculated the frequency maximum utilizable to optimize the system's performance.
工程师计算了可利用的最大频率以优化系统性能。
4.During the meeting, we discussed the frequency maximum utilizable in relation to our new product launch.
在会议中,我们讨论了与新产品发布相关的可利用的最大频率。
5.The research focused on determining the frequency maximum utilizable for various materials under stress.
研究集中在确定各种材料在应力下的可利用的最大频率。
作文
In the study of physics and engineering, understanding the concept of frequency maximum utilizable is crucial for optimizing various systems. The term refers to the highest frequency at which a system can effectively operate without significant loss of performance or efficiency. This principle is particularly important in fields such as telecommunications, audio engineering, and signal processing. For instance, in telecommunications, the frequency maximum utilizable determines the bandwidth that can be used for transmitting data. If the frequency exceeds this limit, the signal may become distorted, leading to poor communication quality.In audio engineering, the frequency maximum utilizable helps sound engineers understand the limits of audio equipment. Each speaker or microphone has a specific range of frequencies it can handle effectively. When sound exceeds this range, it can result in distortion or loss of clarity. Thus, knowing the frequency maximum utilizable of audio devices ensures that music or sound is reproduced accurately, enhancing the listening experience.Moreover, in signal processing, the frequency maximum utilizable plays a vital role in filtering and analyzing signals. Engineers must design filters that allow certain frequencies to pass while blocking others. If the filter operates outside its frequency maximum utilizable, it may not function correctly, leading to erroneous data interpretation. This is particularly critical in medical imaging technologies, where accurate frequency utilization can significantly impact diagnostic outcomes.In practical applications, determining the frequency maximum utilizable involves extensive testing and analysis. Engineers often conduct experiments to measure how a system responds to different frequencies. By identifying the point at which performance begins to degrade, they can establish the optimal operating frequency range. This process not only enhances the efficiency of systems but also extends their lifespan by preventing damage caused by overloading.Furthermore, the concept of frequency maximum utilizable extends beyond technical fields. In everyday life, individuals can apply this principle to manage their time and resources more effectively. Just as systems have a maximum frequency for optimal performance, people also have limits on how much they can handle at once. Recognizing these limits can lead to better productivity and reduced stress.For example, when juggling multiple tasks, understanding one’s frequency maximum utilizable can help prioritize activities and allocate time efficiently. Overcommitting can lead to burnout, just as exceeding a system's frequency limit can lead to failure. Therefore, applying this concept in personal management can foster a healthier work-life balance.In conclusion, the term frequency maximum utilizable encapsulates a fundamental principle that applies across various domains, from engineering to personal productivity. By recognizing and respecting these limits, whether in technology or daily life, we can optimize performance, enhance efficiency, and ultimately achieve better results. Understanding the frequency maximum utilizable allows us to navigate complex systems and make informed decisions that promote success and well-being.
在物理和工程学的研究中,理解“频率最大可利用”的概念对于优化各种系统至关重要。这个术语指的是一个系统可以有效运行而不会显著损失性能或效率的最高频率。这个原则在电信、音频工程和信号处理等领域尤其重要。例如,在电信中,“频率最大可利用”决定了用于传输数据的带宽。如果频率超过这个限制,信号可能会失真,导致通信质量下降。在音频工程中,“频率最大可利用”帮助声音工程师理解音频设备的极限。每个扬声器或麦克风都有其能够有效处理的特定频率范围。当声音超出这个范围时,可能会导致失真或清晰度丧失。因此,了解音频设备的“频率最大可利用”可以确保音乐或声音被准确再现,从而增强听觉体验。此外,在信号处理领域,“频率最大可利用”在过滤和分析信号中起着至关重要的作用。工程师必须设计允许某些频率通过而阻止其他频率的滤波器。如果滤波器在其“频率最大可利用”之外工作,可能无法正常运行,导致数据解读错误。这在医疗成像技术中尤为关键,因为准确的频率利用可以显著影响诊断结果。在实际应用中,确定“频率最大可利用”涉及广泛的测试和分析。工程师通常进行实验,以测量系统对不同频率的响应。通过识别性能开始下降的点,他们可以建立最佳操作频率范围。这个过程不仅提高了系统的效率,还通过防止由于过载造成的损坏来延长其使用寿命。此外,“频率最大可利用”的概念超越了技术领域。在日常生活中,个人可以应用这一原则更有效地管理时间和资源。正如系统有一个最大频率以实现最佳性能,人们也有处理一次性事务的极限。认识到这些限制可以导致更好的生产力和减少压力。例如,在处理多项任务时,理解自己的“频率最大可利用”可以帮助优先排序活动并有效分配时间。过度承诺可能导致精疲力竭,就像超过系统的频率限制会导致故障。因此,在个人管理中应用这一概念可以促进更健康的工作与生活平衡。总之,术语“频率最大可利用”概括了一个适用于各个领域的基本原则,从工程到个人生产力。通过认识和尊重这些限制,无论是在技术还是日常生活中,我们都可以优化性能,提高效率,并最终取得更好的结果。理解“频率最大可利用”使我们能够驾驭复杂的系统,做出促进成功和幸福的明智决策。
相关单词
