crystal control

简明释义

晶体控制

英英释义

例句

1.The telecommunications company invested in crystal control systems to improve signal clarity.

这家电信公司投资于晶体控制系统，以改善信号清晰度。

2.In our laboratory, we utilize crystal control to maintain precise measurements in our experiments.

在我们的实验室中，我们利用晶体控制来保持实验中的精确测量。

3.The new radio system features advanced crystal control technology for better frequency stability.

新无线电系统采用先进的晶体控制技术，以提高频率稳定性。

4.For optimal sound quality, the audio equipment is designed with crystal control to minimize distortion.

为了获得最佳音质，音频设备采用晶体控制设计，以最小化失真。

5.The watchmaker explained how crystal control ensures the accuracy of timekeeping in high-end watches.

钟表匠解释了晶体控制如何确保高端手表的计时准确性。

作文

In the realm of technology and engineering, the term crystal control refers to the precise regulation and management of crystal oscillators, which are essential components in various electronic devices. These oscillators are responsible for generating stable frequencies that ensure accurate timing and synchronization in circuits. The importance of crystal control cannot be overstated, as it plays a crucial role in the functionality of everything from smartphones to satellite communications.The concept of crystal control is rooted in the principles of piezoelectricity. When mechanical stress is applied to certain materials, they generate an electrical charge. Conversely, when an electric field is applied to these materials, they change shape. This property is harnessed in quartz crystals, which are commonly used in oscillators due to their ability to maintain a consistent frequency over a wide range of temperatures and conditions.Effective crystal control involves not only the selection of the right type of crystal but also the implementation of circuitry that can adjust the frequency output as needed. Engineers must consider factors such as load capacitance, temperature stability, and aging effects when designing systems that rely on crystal oscillators. By employing techniques such as temperature compensation and phase-locked loops, engineers can enhance the reliability and performance of these systems.One of the most significant applications of crystal control is in the field of telecommunications. Modern communication systems require precise timing to synchronize data transmission between devices. A slight deviation in frequency can lead to data loss or corruption, making crystal control an integral part of maintaining the integrity of communication networks. For instance, GPS satellites utilize highly accurate crystal oscillators to ensure that they can provide precise location data to users on Earth.In addition to telecommunications, crystal control is vital in the manufacturing of computer processors. As technology advances and processors become faster and more complex, the need for accurate timing becomes even more critical. Engineers are continually developing new methods to improve crystal control to meet the demands of modern computing.Moreover, the advancements in crystal control technology have led to innovations in consumer electronics. Devices such as smartwatches and fitness trackers rely heavily on accurate timing mechanisms to function correctly. The miniaturization of crystal oscillators has allowed these devices to maintain high performance while fitting into compact designs.As we look to the future, the significance of crystal control will undoubtedly continue to grow. With the rise of the Internet of Things (IoT) and the increasing interconnectivity of devices, the need for precise timing and synchronization will become even more pronounced. Engineers and researchers are already exploring new materials and technologies to enhance crystal control, ensuring that our electronic devices remain reliable and efficient.In conclusion, crystal control is a fundamental aspect of modern electronics that ensures the accuracy and reliability of various devices. Its applications span across multiple industries, highlighting its importance in both everyday technology and advanced engineering solutions. As we continue to innovate and develop new technologies, understanding and mastering crystal control will be essential for future advancements in the field.

在技术和工程领域，术语crystal control指的是对晶体振荡器的精确调节和管理，这些振荡器是各种电子设备中的重要组成部分。这些振荡器负责生成稳定的频率，以确保电路中的准确计时和同步。crystal control的重要性不容小觑，因为它在从智能手机到卫星通信等所有设备的功能中都起着至关重要的作用。crystal control的概念根植于压电效应的原理。当对某些材料施加机械应力时，它们会产生电荷。相反，当对这些材料施加电场时，它们会改变形状。这一特性在石英晶体中得到了应用，石英晶体由于其在广泛的温度和条件下保持一致频率的能力而被广泛用于振荡器。有效的crystal control不仅涉及选择合适类型的晶体，还涉及实施能够根据需要调整频率输出的电路。工程师在设计依赖于晶体振荡器的系统时必须考虑负载电容、温度稳定性和老化效应等因素。通过采用温度补偿和锁相环等技术，工程师可以增强这些系统的可靠性和性能。crystal control最重要的应用之一是在电信领域。现代通信系统需要精确的计时来同步设备之间的数据传输。频率的微小偏差可能导致数据丢失或损坏，使得crystal control成为维护通信网络完整性的一个不可或缺的部分。例如，GPS卫星利用高度准确的晶体振荡器来确保它们能够向地球上的用户提供精确的位置数据。除了电信之外，crystal control在计算机处理器的制造中也至关重要。随着技术的进步和处理器变得越来越快和复杂，对准确计时的需求变得更加关键。工程师们正在不断开发新方法来改善crystal control以满足现代计算的需求。此外，crystal control技术的进步导致了消费电子产品的创新。诸如智能手表和健身追踪器等设备在正常运行中严重依赖准确的计时机制。晶体振荡器的小型化使这些设备能够在紧凑的设计中保持高性能。展望未来，crystal control的重要性无疑将继续增长。随着物联网（IoT）的兴起和设备之间日益增加的互联性，对精确计时和同步的需求将变得更加明显。工程师和研究人员已经在探索新材料和技术，以增强crystal control，确保我们的电子设备保持可靠和高效。总之，crystal control是现代电子学的一个基本方面，确保各种设备的准确性和可靠性。它的应用跨越多个行业，突显了它在日常技术和先进工程解决方案中的重要性。随着我们继续创新和开发新技术，理解和掌握crystal control将对该领域未来的进步至关重要。