time base accuracy

简明释义

时基准确度

英英释义

例句

1.The GPS technology relies heavily on time base accuracy 时间基准精度 to provide accurate location data.

GPS技术严重依赖于时间基准精度来提供准确的位置数据。

2.Our research showed that improving time base accuracy 时间基准精度 can significantly reduce errors in data collection.

我们的研究表明，提高时间基准精度可以显著减少数据收集中的错误。

3.The new clock system was designed to enhance the time base accuracy 时间基准精度 of our laboratory experiments.

新的钟表系统旨在提高我们实验室实验的时间基准精度。

4.Engineers must consider time base accuracy 时间基准精度 when designing navigation systems.

工程师在设计导航系统时必须考虑时间基准精度。

5.In telecommunications, maintaining time base accuracy 时间基准精度 is crucial for synchronizing signals.

在电信领域，保持时间基准精度对于信号同步至关重要。

作文

In today's fast-paced world, where technology drives almost every aspect of our lives, the concept of time base accuracy has become increasingly important. 时间基准准确性 refers to the precision with which time intervals are measured and maintained in various systems, particularly in fields such as telecommunications, computing, and scientific research. As we delve deeper into the significance of time base accuracy, we can appreciate how it influences our daily activities and the functioning of complex systems.To begin with, let us consider the role of time base accuracy in telecommunications. Modern communication networks rely heavily on synchronized timing to ensure that data packets are transmitted efficiently and without error. For instance, in mobile networks, the timing of signals is crucial for maintaining call quality and data transfer rates. If the time base accuracy is compromised, it can lead to delays, dropped calls, and a poor user experience. Therefore, telecommunications companies invest significantly in technologies that enhance their systems' time base accuracy, ensuring seamless connectivity for users around the globe.Moreover, in the realm of computing, time base accuracy plays a vital role in the performance of computer systems. Operating systems and applications rely on precise timing to execute processes and manage resources effectively. For example, in real-time systems, such as those used in automotive or aerospace applications, even the slightest deviation in timing can have catastrophic consequences. Engineers must ensure that their designs adhere to strict time base accuracy standards to prevent failures and maintain safety.Scientific research also demands high levels of time base accuracy. In experiments where timing is critical, such as particle physics or astronomical observations, researchers must use highly accurate clocks and timing devices to collect data. Any discrepancies in timing can lead to incorrect conclusions and hinder scientific progress. Thus, the pursuit of improved time base accuracy continues to be a priority in many research institutions.Furthermore, the rise of the Internet of Things (IoT) has brought new challenges and opportunities regarding time base accuracy. As more devices become interconnected, the need for synchronized timing across multiple platforms becomes paramount. IoT applications, such as smart homes and industrial automation, require precise timing to function correctly. A lack of time base accuracy can result in miscommunication between devices, leading to inefficiencies and potential hazards. Therefore, developers must prioritize time base accuracy when designing IoT solutions.In conclusion, time base accuracy is an essential aspect of modern technology that impacts various industries and our everyday lives. Whether in telecommunications, computing, scientific research, or the burgeoning field of IoT, maintaining high levels of time base accuracy is crucial for ensuring efficiency, safety, and reliability. As technology continues to evolve, the emphasis on achieving and maintaining time base accuracy will only grow, highlighting its significance in our increasingly interconnected world.

在当今快节奏的世界中，科技几乎驱动着我们生活的每一个方面，时间基准准确性这一概念变得愈发重要。时间基准准确性指的是在各种系统中测量和维持时间间隔的精确度，特别是在电信、计算机和科学研究等领域。当我们深入探讨时间基准准确性的意义时，可以体会到它如何影响我们的日常活动以及复杂系统的运行。首先，让我们考虑时间基准准确性在电信中的作用。现代通信网络在很大程度上依赖于同步时序，以确保数据包高效且无误地传输。例如，在移动网络中，信号的时序对于保持通话质量和数据传输速率至关重要。如果时间基准准确性受到影响，可能会导致延迟、掉话以及糟糕的用户体验。因此，电信公司在提升其系统的时间基准准确性技术上投入了大量资金，以确保全球用户的无缝连接。此外，在计算机领域，时间基准准确性对计算机系统的性能也起着至关重要的作用。操作系统和应用程序依赖于精确的时序来有效执行进程和管理资源。例如，在汽车或航空航天等应用中使用的实时系统中，即使是最微小的时序偏差也可能产生灾难性的后果。工程师必须确保他们的设计遵循严格的时间基准准确性标准，以防止故障并维护安全。科学研究也对高水平的时间基准准确性有着严格的要求。在某些时间至关重要的实验中，例如粒子物理学或天文观测，研究人员必须使用高精度的时钟和计时设备来收集数据。任何时序上的差异都可能导致错误的结论，并阻碍科学进步。因此，提高时间基准准确性的追求继续成为许多研究机构的重点。此外，物联网（IoT）的兴起带来了有关时间基准准确性的新挑战和机遇。随着越来越多的设备互联互通，多个平台之间需要同步时序显得尤为重要。物联网应用，如智能家居和工业自动化，要求精确的时序才能正常运行。缺乏时间基准准确性可能导致设备之间的误通信，从而导致低效率和潜在的危险。因此，开发人员在设计物联网解决方案时，必须将时间基准准确性放在首位。总之，时间基准准确性是现代技术中的一个重要方面，影响着各个行业以及我们的日常生活。无论是在电信、计算机、科学研究还是新兴的物联网领域，保持高水平的时间基准准确性对于确保效率、安全性和可靠性至关重要。随着技术的不断发展，对实现和维持时间基准准确性的重视只会增加，突显出其在我们日益互联的世界中的重要性。