synchronizing cycle

简明释义

同步周期

英英释义

例句

1.The synchronizing cycle 同步周期 is crucial for maintaining the integrity of the database.

对于维护数据库的完整性，synchronizing cycle 同步周期至关重要。

2.The software update includes a new feature for the synchronizing cycle 同步周期 to improve data consistency.

软件更新包括一个新功能，用于改善数据一致性的synchronizing cycle 同步周期。

3.Adjusting the synchronizing cycle 同步周期 can lead to better performance in cloud computing.

调整synchronizing cycle 同步周期可以提高云计算的性能。

4.The team analyzed the synchronizing cycle 同步周期 to identify potential delays in the project.

团队分析了synchronizing cycle 同步周期以识别项目中的潜在延迟。

5.During the synchronizing cycle 同步周期, all devices must be connected to the network.

在synchronizing cycle 同步周期期间，所有设备必须连接到网络。

作文

In the world of technology and engineering, the term synchronizing cycle refers to a specific interval during which systems or processes align their operations to ensure coherence and efficiency. This concept is particularly crucial in fields such as telecommunications, computer networks, and robotics, where multiple components must work together seamlessly. Understanding the importance of the synchronizing cycle can greatly enhance our ability to design and implement effective systems. To illustrate this, let us consider a simple example of a multi-processor computer system. In such a system, each processor may have its own clock speed and operating rhythm. Without a well-defined synchronizing cycle, these processors could easily fall out of sync, leading to data corruption or inefficiencies in processing tasks. By establishing a synchronizing cycle, all processors can operate in harmony, executing instructions at predetermined intervals that allow for optimal performance. Moreover, the concept of the synchronizing cycle extends beyond just hardware configurations; it also applies to software development. In agile methodologies, for instance, teams often work in sprints, which can be viewed as a form of synchronizing cycle. During each sprint, team members coordinate their efforts to achieve specific goals within a set timeframe. This synchronization fosters collaboration and ensures that everyone is on the same page, ultimately leading to more successful project outcomes. In the realm of telecommunications, the significance of the synchronizing cycle becomes even more apparent. Modern communication systems rely on precise timing to transmit and receive data effectively. For instance, in a cellular network, base stations must synchronize their transmissions to avoid interference and ensure that users experience smooth connectivity. Any disruption in the synchronizing cycle can result in dropped calls or slow data speeds, highlighting the necessity of maintaining a reliable synchronization mechanism. Furthermore, in the context of robotics, the synchronizing cycle plays a pivotal role in ensuring that robotic systems can perform complex tasks autonomously. For example, in a manufacturing setting, multiple robots may be tasked with assembling components on a production line. If these robots do not adhere to a strict synchronizing cycle, they risk colliding with one another or failing to complete their tasks in the correct order. By implementing a synchronization protocol, manufacturers can optimize productivity and minimize errors. In conclusion, the synchronizing cycle is an essential concept that underpins the functionality of various technological systems. Whether in computing, telecommunications, or robotics, the ability to synchronize operations across different components is vital for achieving efficiency and reliability. As we continue to advance in technology, understanding and mastering the principles of the synchronizing cycle will be increasingly important for engineers and developers alike. By prioritizing synchronization in our designs, we can create systems that are not only effective but also resilient to the challenges posed by an ever-evolving technological landscape.

在技术和工程的世界中，术语synchronizing cycle指的是一个特定的时间间隔，在此期间，系统或过程对齐其操作以确保一致性和效率。这个概念在电信、计算机网络和机器人等领域尤为重要，因为多个组件必须无缝协作。理解synchronizing cycle的重要性可以极大地增强我们设计和实施有效系统的能力。为了说明这一点，让我们考虑一个简单的多处理器计算机系统的例子。在这样的系统中，每个处理器可能具有自己的时钟速度和操作节奏。如果没有明确定义的synchronizing cycle，这些处理器很容易失去同步，从而导致数据损坏或处理任务的低效。通过建立synchronizing cycle，所有处理器可以和谐工作，在预定的时间间隔内执行指令，从而实现最佳性能。此外，synchronizing cycle的概念不仅适用于硬件配置；它也适用于软件开发。例如，在敏捷方法论中，团队通常在冲刺中工作，这可以被视为一种synchronizing cycle。在每个冲刺期间，团队成员协调他们的努力，以在设定的时间框架内实现特定目标。这种同步促进了协作，并确保每个人都在同一页面上，最终导致项目成果更成功。在电信领域，synchronizing cycle的重要性变得更加明显。现代通信系统依赖精确的时序来有效地传输和接收数据。例如，在蜂窝网络中，基站必须同步其传输，以避免干扰并确保用户体验流畅的连接。任何在synchronizing cycle中的中断都可能导致通话中断或数据速度缓慢，突显了保持可靠同步机制的必要性。此外，在机器人技术的背景下，synchronizing cycle在确保机器人系统能够自主执行复杂任务方面发挥着关键作用。例如，在制造环境中，多个机器人可能被指派在生产线上组装组件。如果这些机器人不遵循严格的synchronizing cycle，它们就有可能相互碰撞或未能按正确顺序完成任务。通过实施同步协议，制造商可以优化生产力并最小化错误。总之，synchronizing cycle是支撑各种技术系统功能的基本概念。无论是在计算、通信还是机器人领域，跨不同组件同步操作的能力对于实现效率和可靠性至关重要。随着我们在技术上的不断进步，理解和掌握synchronizing cycle的原则对于工程师和开发人员来说将变得越来越重要。通过在我们的设计中优先考虑同步，我们可以创建不仅有效而且能够应对不断变化的技术环境挑战的系统。