basic pulse repetition interval

简明释义

基本脉冲重复周期

英英释义

例句

1.The basic pulse repetition interval 基本脉冲重复间隔 is crucial for maintaining the stability of communication signals.

保持通信信号稳定性至关重要的是 基本脉冲重复间隔 基本脉冲重复间隔 。

2.Engineers need to calculate the basic pulse repetition interval 基本脉冲重复间隔 when designing a new sonar system.

工程师在设计新声纳系统时需要计算 基本脉冲重复间隔 基本脉冲重复间隔 。

3.In radar systems, the basic pulse repetition interval 基本脉冲重复间隔 determines the maximum range of detection.

在雷达系统中，基本脉冲重复间隔 基本脉冲重复间隔 决定了最大探测范围。

4.A shorter basic pulse repetition interval 基本脉冲重复间隔 can lead to better target tracking in military applications.

在军事应用中，较短的 基本脉冲重复间隔 基本脉冲重复间隔 可以实现更好的目标跟踪。

5.Adjusting the basic pulse repetition interval 基本脉冲重复间隔 can improve the resolution of the imaging system.

调整 基本脉冲重复间隔 基本脉冲重复间隔 可以提高成像系统的分辨率。

作文

In the field of telecommunications and radar technology, understanding various metrics is crucial for optimizing performance and ensuring effective communication. One such important metric is the basic pulse repetition interval, which refers to the time duration between successive pulses in a pulsed signal. This interval plays a significant role in determining the efficiency and accuracy of data transmission and reception. In this essay, I will explore the meaning of the basic pulse repetition interval and its implications in different applications.Firstly, the basic pulse repetition interval can be defined as the time gap between two consecutive pulses emitted by a transmitter. This interval is essential because it affects the overall bandwidth and the ability to transmit information. A shorter basic pulse repetition interval allows for more frequent transmissions, which can lead to higher data rates. However, it is important to balance this with the potential for increased noise and interference, which can degrade signal quality.In radar systems, the basic pulse repetition interval is critical for detecting moving objects and measuring their distance. For instance, in a radar application, if the basic pulse repetition interval is too long, the system may not be able to track fast-moving targets effectively. Conversely, if the interval is too short, the radar may experience range ambiguity, where it cannot distinguish between multiple echoes from different ranges. Therefore, engineers must carefully select the basic pulse repetition interval to optimize the radar's performance based on the specific requirements of the application.Moreover, the basic pulse repetition interval has significant implications in wireless communication systems as well. In modern cellular networks, the interval influences how often a base station can communicate with mobile devices. A well-optimized basic pulse repetition interval can enhance the network's capacity to handle multiple users simultaneously, thereby improving overall user experience. Additionally, in technologies such as LiDAR (Light Detection and Ranging), the basic pulse repetition interval determines the density of the point cloud generated, affecting the accuracy and detail of the 3D mapping produced.Furthermore, the basic pulse repetition interval is also a key factor in designing systems for applications like medical imaging. In ultrasound imaging, for example, the interval between sound pulses can influence the resolution and quality of the images obtained. A shorter basic pulse repetition interval can lead to better image clarity, which is vital for accurate diagnostics. Thus, understanding this concept is essential for professionals working in medical technology.In conclusion, the basic pulse repetition interval is a fundamental parameter that significantly impacts various technological domains, including telecommunications, radar systems, wireless communications, and medical imaging. Its definition as the time between successive pulses highlights its importance in ensuring efficient data transmission and accurate measurements. As technology continues to evolve, the optimization of the basic pulse repetition interval will remain a critical focus for engineers and researchers seeking to enhance system performance and functionality.

在电信和雷达技术领域，理解各种指标对于优化性能和确保有效通信至关重要。其中一个重要指标是基本脉冲重复间隔，它指的是脉冲信号中连续脉冲之间的时间持续时间。这个间隔在决定数据传输和接收的效率和准确性方面起着重要作用。在这篇文章中，我将探讨基本脉冲重复间隔的含义及其在不同应用中的影响。首先，基本脉冲重复间隔可以定义为发射器发出两个连续脉冲之间的时间间隔。这个间隔是至关重要的，因为它影响到整体带宽以及传输信息的能力。较短的基本脉冲重复间隔允许更频繁的传输，这可能导致更高的数据传输速率。然而，重要的是要平衡这一点与潜在的噪声和干扰增加，这可能会降低信号质量。在雷达系统中，基本脉冲重复间隔对于检测移动物体和测量其距离至关重要。例如，在雷达应用中，如果基本脉冲重复间隔过长，系统可能无法有效跟踪快速移动的目标。相反，如果间隔过短，雷达可能会经历距离模糊，即无法区分来自不同距离的多个回声。因此，工程师必须仔细选择基本脉冲重复间隔，以根据特定应用的要求优化雷达的性能。此外，基本脉冲重复间隔在无线通信系统中也具有重要影响。在现代蜂窝网络中，间隔影响基站与移动设备之间的通信频率。良好优化的基本脉冲重复间隔可以增强网络同时处理多个用户的能力，从而改善整体用户体验。此外，在激光雷达（LiDAR）等技术中，基本脉冲重复间隔决定了生成的点云密度，影响生成的3D地图的准确性和细节。此外，基本脉冲重复间隔还是设计用于医疗成像应用的系统的关键因素。在超声成像中，例如，声脉冲之间的间隔可以影响获得图像的分辨率和质量。较短的基本脉冲重复间隔可以导致更好的图像清晰度，这对准确诊断至关重要。因此，理解这一概念对从事医疗技术的专业人士来说至关重要。总之，基本脉冲重复间隔是一个基本参数，对电信、雷达系统、无线通信和医疗成像等各个技术领域产生重大影响。它作为连续脉冲之间时间的定义突显了它在确保高效数据传输和准确测量中的重要性。随着技术的不断发展，优化基本脉冲重复间隔将继续是工程师和研究人员寻求提高系统性能和功能的关键焦点。