half pulse recurrence rate delay

简明释义

半脉冲重复频率延时

英英释义

例句

1.Adjusting the half pulse recurrence rate delay 半脉冲重复率延迟 can lead to better synchronization in communication systems.

调整半脉冲重复率延迟可以在通信系统中实现更好的同步。

2.Understanding the half pulse recurrence rate delay 半脉冲重复率延迟 is crucial for accurate signal processing.

理解半脉冲重复率延迟对于准确的信号处理至关重要。

3.Engineers need to calibrate the half pulse recurrence rate delay 半脉冲重复率延迟 to enhance performance in high-frequency applications.

工程师需要校准半脉冲重复率延迟以提高高频应用中的性能。

4.The research paper discusses the impact of half pulse recurrence rate delay 半脉冲重复率延迟 on data transmission rates.

这篇研究论文讨论了半脉冲重复率延迟对数据传输速率的影响。

5.The system's efficiency improved significantly after we optimized the half pulse recurrence rate delay 半脉冲重复率延迟 settings.

在我们优化了半脉冲重复率延迟设置后，系统的效率显著提高。

作文

In the realm of signal processing and telecommunications, understanding various technical terms is crucial for effective communication and implementation of systems. One such term that often arises in discussions about system performance is half pulse recurrence rate delay. This term refers to a specific delay encountered in signal transmission, particularly when dealing with pulsed signals. To grasp its significance, we must first understand the components of this phrase. The term 'half pulse' indicates that we are discussing a pulse that is only half the duration of a standard pulse. Pulses are essential in digital communications as they represent bits of information. A half pulse, therefore, can be seen as a representation of a binary state but in a more condensed form. This leads us to the next part of the term: 'recurrence rate.' The recurrence rate refers to how often these pulses occur within a given timeframe. In many systems, maintaining a high recurrence rate is vital for ensuring data integrity and minimizing delays in transmission. However, with any signal transmission, delays are inevitable. This is where the concept of half pulse recurrence rate delay becomes relevant. It describes the delay experienced when the system processes these half pulses at their designated recurrence rate. Understanding this delay is essential for engineers and technicians who are tasked with optimizing communication systems. If the delay is too long, it can lead to significant issues such as data loss or corruption, which can severely impact the performance of the network. Moreover, the implications of half pulse recurrence rate delay extend beyond just telecommunications. In various applications, including medical imaging and radar systems, managing pulse delays is critical. For instance, in medical imaging technologies like MRI, the timing of pulse sequences can affect image quality and diagnostic accuracy. Thus, professionals in these fields must have a solid understanding of the delays associated with different pulse types to ensure optimal performance.In conclusion, the term half pulse recurrence rate delay encapsulates a complex interaction between pulse duration and transmission frequency, highlighting the importance of timing in signal processing. As technology continues to advance, the ability to manage and mitigate such delays will be paramount. Engineers and researchers must continue to explore innovative solutions to enhance system performance while maintaining the integrity of the transmitted data. By doing so, we can ensure that our communication systems remain efficient and reliable, paving the way for future advancements in technology.

在信号处理和电信领域，理解各种技术术语对于有效的沟通和系统实施至关重要。一个在讨论系统性能时经常出现的术语是半脉冲重现率延迟。这个术语指的是在信号传输中遇到的一种特定延迟，特别是在处理脉冲信号时。要理解其重要性，我们首先必须了解这个短语的组成部分。术语“半脉冲”表示我们正在讨论的脉冲只有标准脉冲的一半持续时间。脉冲在数字通信中是至关重要的，因为它们代表信息的位。因此，半脉冲可以被视为以更紧凑的形式表示二进制状态。这引出了术语的下一个部分：“重现率”。重现率指的是这些脉冲在给定时间内发生的频率。在许多系统中，保持高重现率对于确保数据完整性和最小化传输延迟是至关重要的。然而，在任何信号传输中，延迟都是不可避免的。这就是半脉冲重现率延迟概念变得相关的地方。它描述了系统在以指定重现率处理这些半脉冲时所经历的延迟。理解这一延迟对于负责优化通信系统的工程师和技术人员至关重要。如果延迟过长，可能会导致重大问题，如数据丢失或损坏，这会严重影响网络的性能。此外，半脉冲重现率延迟的影响不仅限于电信。在各种应用中，包括医学成像和雷达系统，管理脉冲延迟至关重要。例如，在医学成像技术如MRI中，脉冲序列的时序可能会影响图像质量和诊断准确性。因此，这些领域的专业人士必须对不同脉冲类型的延迟有扎实的理解，以确保最佳性能。总之，术语半脉冲重现率延迟概括了脉冲持续时间和传输频率之间的复杂相互作用，突显了信号处理中的时机重要性。随着技术的不断进步，管理和减轻此类延迟的能力将变得至关重要。工程师和研究人员必须继续探索创新解决方案，以提高系统性能，同时保持传输数据的完整性。通过这样做，我们可以确保我们的通信系统保持高效和可靠，为未来技术的进步铺平道路。