transient fault

简明释义

瞬时故障

英英释义

例句

1.The system experienced a transient fault 瞬态故障 during the power surge, causing temporary disruptions.

系统在电力激增期间经历了一个瞬态故障，导致暂时的中断。

2.During testing, we encountered a transient fault 瞬态故障 that was difficult to replicate.

在测试过程中，我们遇到了一个难以复制的瞬态故障。

3.The software is designed to handle transient faults 瞬态故障 gracefully without crashing.

该软件旨在优雅地处理瞬态故障而不会崩溃。

4.Engineers are working to identify the cause of the transient fault 瞬态故障 that affected the network stability.

工程师们正在努力找出影响网络稳定性的瞬态故障的原因。

5.A transient fault 瞬态故障 in the circuit board led to unexpected behavior in the device.

电路板上的瞬态故障导致设备出现意外行为。

作文

In the world of technology and electronics, understanding the concept of a transient fault is crucial for engineers and developers. A transient fault refers to a temporary error that occurs in a system, often caused by external disturbances such as electrical surges, electromagnetic interference, or even environmental factors like temperature changes. Unlike permanent faults, which can lead to catastrophic failures and require significant repairs, transient faults are typically short-lived and may resolve themselves without any intervention. This characteristic makes them particularly challenging to diagnose and address.One of the most common examples of a transient fault can be found in computer systems. For instance, when a power surge occurs, it can momentarily disrupt the operation of a computer, causing it to freeze or crash. However, once the surge passes, the system often returns to normal functionality without any lasting damage. This phenomenon can also be observed in communication networks, where brief interruptions in signal quality can lead to data packet loss or delays. Engineers must design systems with robust error detection and correction mechanisms to handle these transient faults effectively.The implications of transient faults extend beyond individual devices; they can affect entire networks and infrastructures. For example, in power distribution systems, a sudden spike in voltage can cause protective relays to trip, leading to power outages. These outages may not be due to a fault in the system itself but rather a transient fault that temporarily exceeds operational thresholds. Understanding this distinction is vital for utility companies to minimize downtime and restore services quickly.To mitigate the impact of transient faults, various strategies can be employed. One approach is to implement redundant systems that can take over in case of a fault. For instance, in critical applications such as aerospace and medical devices, having backup systems ensures that operations can continue smoothly, even if a transient fault occurs in one part of the system. Additionally, regular maintenance and monitoring can help identify patterns that may indicate an increased likelihood of transient faults, allowing for preemptive measures to be taken.Furthermore, advancements in technology have led to the development of more resilient systems that can withstand transient faults. For example, modern integrated circuits are designed with built-in error correction capabilities that can detect and correct errors caused by transient disturbances. This not only improves reliability but also enhances the overall performance of electronic devices.In conclusion, the understanding of transient faults is essential for anyone involved in the fields of engineering and technology. As systems become increasingly complex and interconnected, the ability to recognize, diagnose, and mitigate the effects of transient faults will play a critical role in ensuring the reliability and efficiency of our technological infrastructure. By continuing to innovate and improve our approaches to handling these temporary errors, we can create systems that are not only more resilient but also capable of delivering uninterrupted service to users around the world.

在科技和电子产品的世界中，理解瞬态故障的概念对工程师和开发人员至关重要。瞬态故障是指系统中发生的暂时性错误，通常由外部干扰引起，如电涌、电磁干扰或环境因素（如温度变化）。与永久性故障不同，后者可能导致灾难性故障并需要重大修复，瞬态故障通常是短暂的，可能在没有任何干预的情况下自行解决。这一特性使得它们特别难以诊断和处理。一个常见的瞬态故障例子可以在计算机系统中找到。例如，当发生电涌时，它可能会暂时干扰计算机的操作，导致其冻结或崩溃。然而，一旦电涌过去，系统通常会恢复正常功能，而不会造成任何持久性损坏。这种现象也可以在通信网络中观察到，其中信号质量的短暂中断可能导致数据包丢失或延迟。工程师必须设计具有强大错误检测和纠正机制的系统，以有效处理这些瞬态故障。瞬态故障的影响不仅限于单个设备；它们还可以影响整个网络和基础设施。例如，在电力分配系统中，电压的突然激增可能导致保护继电器跳闸，从而导致停电。这些停电可能不是由于系统本身的故障，而是由于暂时超过操作阈值的瞬态故障。理解这一区别对公用事业公司至关重要，以尽量减少停机时间并迅速恢复服务。为了减轻瞬态故障的影响，可以采取各种策略。一种方法是实施冗余系统，以便在发生故障时可以接管。例如，在航空航天和医疗设备等关键应用中，拥有备份系统可确保即使系统的某一部分发生瞬态故障，操作仍能顺利进行。此外，定期维护和监控可以帮助识别可能表明瞬态故障发生概率增加的模式，从而采取预防措施。此外，技术的进步导致开发出更具韧性的系统，能够承受瞬态故障。例如，现代集成电路设计了内置的错误校正功能，可以检测和纠正由瞬态干扰引起的错误。这不仅提高了可靠性，还增强了电子设备的整体性能。总之，理解瞬态故障对任何参与工程和技术领域的人来说都是至关重要的。随着系统变得越来越复杂和互联，识别、诊断和减轻瞬态故障影响的能力将在确保我们技术基础设施的可靠性和效率方面发挥关键作用。通过继续创新和改善我们处理这些暂时性错误的方法，我们可以创建不仅更具韧性，而且能够为全球用户提供不间断服务的系统。