primary secondary clock

简明释义

子母钟

英英释义

例句

1.In our network setup, we rely on a primary secondary clock 主从时钟 to ensure accurate timekeeping for transactions.

在我们的网络设置中，我们依赖主从时钟来确保交易的准确计时。

2.The primary secondary clock 主从时钟 system is crucial for synchronizing audio and video streams in live broadcasts.

在直播中，主从时钟系统对于同步音频和视频流至关重要。

3.The engineer explained how the primary secondary clock 主从时钟 system works in synchronizing data across multiple devices.

工程师解释了如何在多个设备之间同步数据的主从时钟系统是如何工作的。

4.For our application, we implemented a primary secondary clock 主从时钟 model to improve performance and reliability.

为了我们的应用程序，我们实施了一个主从时钟模型，以提高性能和可靠性。

5.The primary secondary clock 主从时钟 configuration helps prevent data loss during server maintenance.

在服务器维护期间，主从时钟配置有助于防止数据丢失。

作文

In the realm of timekeeping and synchronization, the terms primary secondary clock refer to a system where multiple clocks are used in conjunction to maintain accurate time across different devices or locations. The concept is especially crucial in fields such as telecommunications, data centers, and various scientific applications where precise timing is essential. Understanding the relationship between the primary secondary clock is vital for ensuring that systems operate smoothly and efficiently.A primary secondary clock system typically consists of a primary clock that serves as the main reference point for timekeeping. This clock is responsible for generating a standard time signal that other clocks, known as secondary clocks, will follow. The primary clock is usually highly accurate and may be synchronized with atomic time standards or GPS signals to ensure its precision.Secondary clocks, on the other hand, rely on the signal provided by the primary clock to maintain their own time. These clocks can be distributed across various locations, receiving the time signal from the primary clock through wired or wireless communication methods. This setup allows for a uniform time display across all secondary clocks, which is crucial in environments where coordination is necessary, such as in financial markets, broadcast networks, and transportation systems.One of the key advantages of employing a primary secondary clock system is the ability to achieve redundancy and reliability. If the primary clock fails or experiences a malfunction, secondary clocks can still function based on their last received signal, providing a buffer against total time loss. Furthermore, this hierarchical structure allows for easier maintenance and upgrades; if a secondary clock needs to be replaced or recalibrated, it can be done without disrupting the entire system.In the context of modern technology, the importance of a primary secondary clock system cannot be overstated. With the rise of the Internet of Things (IoT) and smart devices, precise time synchronization has become even more critical. Devices that communicate with each other must do so in a timely manner to ensure data integrity and operational efficiency. A well-implemented primary secondary clock setup can help mitigate issues related to latency and timing discrepancies, which can lead to errors in data transmission and processing.Moreover, industries that rely heavily on data analysis and real-time processing, such as artificial intelligence and machine learning, benefit greatly from a reliable primary secondary clock framework. By ensuring that all components of a system are synchronized, organizations can enhance their analytical capabilities and make more informed decisions based on accurate data.In conclusion, the concept of primary secondary clock is fundamental to the effective management of time in various technological and scientific domains. By establishing a primary clock that serves as the benchmark for timekeeping, and utilizing secondary clocks to disseminate this information, systems can achieve high levels of accuracy, reliability, and efficiency. As we continue to advance into an era dominated by interconnected devices and rapid data exchange, understanding and implementing a primary secondary clock system will be crucial for success in many fields.

在计时和同步的领域中，术语primary secondary clock指的是一个系统，其中多个时钟结合使用，以保持不同设备或位置之间的准确时间。这一概念在电信、数据中心以及各种科学应用等领域尤为重要，因为精确的计时至关重要。理解primary secondary clock之间的关系对于确保系统平稳高效地运行至关重要。一个primary secondary clock系统通常由一个主要时钟组成，该时钟作为计时的主要参考点。这个时钟负责生成一个标准时间信号，其他被称为次级时钟的时钟将遵循这个信号。主要时钟通常非常准确，可能与原子时间标准或GPS信号同步，以确保其精确性。另一方面，次级时钟依赖于主要时钟提供的信号来保持自己的时间。这些时钟可以分布在各个位置，通过有线或无线通信方式接收来自主要时钟的时间信号。这个设置允许所有次级时钟显示统一的时间，这在需要协调的环境中至关重要，例如金融市场、广播网络和交通系统。采用primary secondary clock系统的一个主要优势是能够实现冗余和可靠性。如果主要时钟发生故障或出现故障，次级时钟仍然可以根据最后接收到的信号继续工作，从而为完全丧失时间提供缓冲。此外，这种分层结构允许更容易的维护和升级；如果需要更换或重新校准次级时钟，可以在不干扰整个系统的情况下进行。在现代技术背景下，primary secondary clock系统的重要性不可低估。随着物联网（IoT）和智能设备的兴起，精确的时间同步变得更加关键。相互通信的设备必须及时进行，以确保数据完整性和操作效率。一个良好实施的primary secondary clock设置可以帮助减轻与延迟和时间差异相关的问题，这可能导致数据传输和处理中的错误。此外，依赖数据分析和实时处理的行业，如人工智能和机器学习，极大地受益于可靠的primary secondary clock框架。通过确保系统的所有组件都同步，组织可以增强其分析能力，并基于准确的数据做出更明智的决策。总之，primary secondary clock的概念对于有效管理各种技术和科学领域的时间至关重要。通过建立一个作为计时基准的主要时钟，并利用次级时钟传播这些信息，系统可以实现高水平的准确性、可靠性和效率。随着我们继续迈入一个以互联设备和快速数据交换为主导的时代，理解和实施primary secondary clock系统将对许多领域的成功至关重要。