crystal control

简明释义

晶体控制石英稳定

英英释义

例句

1.The engineer explained how crystal control 晶体控制 is essential for maintaining the accuracy of the clock.

工程师解释了如何 晶体控制 crystal control 对于保持时钟的准确性至关重要。

2.Manufacturers rely on crystal control 晶体控制 to improve the stability of their electronic devices.

制造商依赖 晶体控制 crystal control 来提高其电子设备的稳定性。

3.In radio communications, crystal control 晶体控制 ensures that signals are transmitted at the correct frequency.

在无线电通信中，晶体控制 crystal control 确保信号以正确的频率传输。

4.During the presentation, he highlighted the role of crystal control 晶体控制 in modern telecommunications.

在演讲中，他强调了 晶体控制 crystal control 在现代电信中的作用。

5.The lab technician used crystal control 晶体控制 techniques to calibrate the measurement instruments.

实验室技术员使用 晶体控制 crystal control 技术来校准测量仪器。

作文

In recent years, the term crystal control has gained significant attention in various fields, particularly in technology and telecommunications. It refers to the precise regulation and stabilization of frequency signals using crystal oscillators. These oscillators are essential components in modern electronic devices, providing accurate timing and frequency reference. The concept of crystal control is crucial for ensuring that devices operate smoothly and efficiently, as even the slightest deviation in frequency can lead to performance issues or system failures.The importance of crystal control can be seen in everyday technology. For instance, in smartphones, GPS systems, and computers, crystal oscillators help synchronize operations and maintain data integrity. Without effective crystal control, these devices would struggle to perform tasks accurately, leading to user frustration and potential data loss.Moreover, the advancements in crystal control technology have enabled the development of more sophisticated applications. In the field of telecommunications, for example, precise frequency control is vital for managing signals transmitted over long distances. This ensures clear communication and reduces the risk of interference from other signals. As a result, industries heavily reliant on communication networks, such as broadcasting and internet services, benefit immensely from improved crystal control methods.Notably, the evolution of crystal control has also impacted the realm of scientific research. In areas such as quantum computing and particle physics, researchers require highly stable frequency references to conduct experiments accurately. The integration of advanced crystal control technologies allows for the achievement of unprecedented precision in measurements, which is crucial for validating theoretical models and advancing scientific knowledge.Furthermore, the environmental implications of crystal control should not be overlooked. As technology continues to evolve, there is a growing need for energy-efficient solutions. Innovations in crystal control can lead to reduced power consumption in devices, contributing to sustainability efforts. By optimizing the performance of electronic components, manufacturers can create products that not only meet consumer demands but also minimize their ecological footprint.In conclusion, the significance of crystal control extends far beyond its technical definition. It plays a pivotal role in enhancing the functionality of electronic devices, improving communication systems, facilitating scientific research, and promoting environmental sustainability. As we continue to rely on technology in our daily lives, understanding and mastering the principles of crystal control will be essential for future innovations and advancements. Embracing this knowledge will empower individuals and industries alike to harness the full potential of technology, paving the way for a more connected and efficient world.

近年来，“晶体控制”这一术语在各个领域，尤其是技术和电信领域，受到了广泛关注。它指的是利用晶体振荡器对频率信号进行精确调节和稳定。这些振荡器是现代电子设备中的重要组成部分，提供准确的时序和频率参考。“晶体控制”的概念对于确保设备平稳高效地运行至关重要，因为即使是最轻微的频率偏差也会导致性能问题或系统故障。“晶体控制”的重要性可以在日常技术中看到。例如，在智能手机、GPS系统和计算机中，晶体振荡器帮助同步操作并维护数据完整性。如果没有有效的“晶体控制”，这些设备将难以准确执行任务，导致用户沮丧和潜在的数据丢失。此外，晶体控制技术的进步使得更复杂应用的发展成为可能。在电信领域，精确的频率控制对于管理长距离传输的信号至关重要。这确保了清晰的通信，并减少了其他信号干扰的风险。因此，重度依赖通信网络的行业，如广播和互联网服务，极大地受益于改进的晶体控制方法。值得注意的是，晶体控制的演变也影响了科学研究领域。在量子计算和粒子物理等领域，研究人员需要高度稳定的频率参考来准确进行实验。先进的晶体控制技术的集成使得在测量中达到前所未有的精度成为可能，这对于验证理论模型和推动科学知识的发展至关重要。此外，晶体控制的环境影响也不容忽视。随着技术的不断发展，对节能解决方案的需求日益增加。晶体控制的创新可以减少设备的功耗，有助于可持续发展努力。通过优化电子元件的性能，制造商可以创造出不仅满足消费者需求而且最小化生态足迹的产品。总之，“晶体控制”的重要性远远超出了其技术定义。它在增强电子设备功能、改善通信系统、促进科学研究和推动环境可持续性方面发挥着关键作用。随着我们在日常生活中继续依赖技术，理解和掌握晶体控制的原理将对未来的创新和进步至关重要。拥抱这一知识将使个人和行业能够充分利用技术的潜力，为一个更加互联和高效的世界铺平道路。