delayed coincidence circuit

简明释义

延迟符合电路

英英释义

例句

1.In particle physics experiments, a delayed coincidence circuit 延迟重合电路 is essential for detecting simultaneous events.

在粒子物理实验中，delayed coincidence circuit 延迟重合电路对于检测同时发生的事件至关重要。

2.We implemented a delayed coincidence circuit 延迟重合电路 to reduce false positives in our signal detection system.

我们实施了一个delayed coincidence circuit 延迟重合电路以减少信号检测系统中的误报。

3.The design of the delayed coincidence circuit 延迟重合电路 requires careful consideration of component tolerances.

delayed coincidence circuit 延迟重合电路的设计需要仔细考虑元件公差。

4.The engineer explained how the delayed coincidence circuit 延迟重合电路 can improve the timing accuracy in our system.

工程师解释了如何通过使用delayed coincidence circuit 延迟重合电路来提高我们系统的时间准确性。

5.A delayed coincidence circuit 延迟重合电路 can help in timing applications where precise synchronization is required.

在需要精确同步的时序应用中，delayed coincidence circuit 延迟重合电路可以提供帮助。

作文

In the realm of electronics and signal processing, various circuits play crucial roles in ensuring accurate and efficient operations. One such circuit is the delayed coincidence circuit, which serves a specific purpose in timing and synchronization tasks. Understanding how this circuit works can provide valuable insights into its applications and significance in modern technology.A delayed coincidence circuit is designed to detect events that occur simultaneously or within a specific time frame. The key feature of this circuit is its ability to introduce a delay in the signal processing, allowing it to compare incoming signals over a defined period. This is particularly useful in applications such as particle physics experiments, where precise timing is essential for capturing data from high-speed events.The operation of a delayed coincidence circuit typically involves two or more input signals. When these signals are received, the circuit processes them by introducing a delay to one or more of the signals. This delay allows the circuit to check if the signals coincide within a predetermined time window. If they do, the circuit generates an output signal indicating a 'coincidence.' This functionality is crucial in scenarios where events happen rapidly and need to be accurately recorded.For instance, in a particle detector setup, particles may collide and produce multiple signals in a very short time span. A delayed coincidence circuit can help identify which signals are related to the same event by checking if they occur within the specified time delay. This capability enhances the accuracy of data collection and reduces the chances of false positives, which can occur when unrelated signals are mistakenly interpreted as coincident events.Moreover, the design of a delayed coincidence circuit can vary depending on the specific requirements of the application. Some circuits might use analog components, while others may be implemented using digital logic. The choice between these implementations often depends on factors such as speed, complexity, and cost. Regardless of the design, the fundamental principle remains the same: to detect coincident events with a controlled delay.In addition to scientific applications, delayed coincidence circuits also find uses in everyday technology. For example, they can be utilized in security systems that require simultaneous activation of multiple sensors. By employing this type of circuit, the system can ensure that an alarm is triggered only when all designated sensors are activated within a specific timeframe, thus reducing false alarms caused by isolated triggers.Furthermore, the concept of coincidence detection extends beyond electronics. In cognitive science, researchers study how humans perceive simultaneous events. The principles behind a delayed coincidence circuit can provide insights into how our brains process timing and synchronicity, offering a fascinating intersection between technology and human cognition.In conclusion, the delayed coincidence circuit is a vital component in various electronic systems, enabling precise timing and synchronization. Its ability to detect coincident signals with a controlled delay makes it indispensable in fields ranging from particle physics to security systems. As technology continues to advance, understanding and utilizing circuits like the delayed coincidence circuit will remain essential for improving the accuracy and efficiency of electronic devices and systems.

在电子和信号处理领域，各种电路在确保操作的准确性和效率方面发挥着至关重要的作用。其中一个电路是延迟重合电路，它在定时和同步任务中服务特定目的。理解这个电路的工作原理可以为我们提供对其应用和现代技术中重要性的宝贵见解。延迟重合电路旨在检测同时发生或在特定时间范围内发生的事件。该电路的关键特征是能够在信号处理过程中引入延迟，从而允许它在定义的时间段内比较输入信号。这在粒子物理实验等应用中尤其有用，因为在捕获高速事件的数据时，精确的时序至关重要。延迟重合电路的操作通常涉及两个或多个输入信号。当接收到这些信号时，电路通过对一个或多个信号引入延迟进行处理。这个延迟使电路能够检查信号是否在预定时间窗口内重合。如果它们确实如此，电路将生成一个输出信号，指示'重合'。这种功能在事件发生迅速且需要准确记录的场景中特别重要。例如，在粒子探测器设置中，粒子可能会在非常短的时间内碰撞并产生多个信号。延迟重合电路可以通过检查信号是否在指定的时间延迟内发生来帮助识别哪些信号与同一事件相关。这种能力提高了数据收集的准确性，并减少了由于误解不相关信号而导致的假阳性情况。此外，延迟重合电路的设计可以根据应用的具体要求而有所不同。有些电路可能使用模拟组件，而另一些则可能使用数字逻辑实现。选择这些实现之间的选择通常取决于速度、复杂性和成本等因素。无论设计如何，其基本原理保持不变：在控制延迟的情况下检测重合事件。除了科学应用外，延迟重合电路还在日常技术中找到了应用。例如，它们可以用于需要多个传感器同时激活的安全系统。通过采用这种类型的电路，系统可以确保仅当所有指定传感器在特定时间框架内激活时才触发警报，从而减少由单独触发引起的误报。此外，重合检测的概念超越了电子学。在认知科学中，研究人员研究人类如何感知同时发生的事件。延迟重合电路背后的原理可以为我们提供关于大脑如何处理时序和同步性的见解，提供了技术与人类认知之间的迷人交集。总之，延迟重合电路是各种电子系统中的重要组件，使精确的定时和同步成为可能。它检测带有控制延迟的重合信号的能力使其在从粒子物理到安全系统的各个领域中不可或缺。随着技术的不断进步，理解和利用像延迟重合电路这样的电路将继续对提高电子设备和系统的准确性和效率至关重要。