pulse phasing

简明释义

脉冲相位蝶

英英释义

例句

1.The concept of pulse phasing 脉冲相位 is applied in various fields, including medical imaging.

在包括医学成像等多个领域中应用了脉冲相位的概念。

2.Understanding pulse phasing 脉冲相位 is essential for engineers working with laser technologies.

理解脉冲相位 对于从事激光技术的工程师来说是必不可少的。

3.During the experiment, the researchers adjusted the pulse phasing 脉冲相位 to achieve better results.

在实验过程中，研究人员调整了脉冲相位以获得更好的结果。

4.In radar technology, pulse phasing 脉冲相位 helps improve target detection accuracy.

在雷达技术中，脉冲相位 有助于提高目标检测的准确性。

5.The technician explained that pulse phasing 脉冲相位 is crucial for optimizing signal transmission in communication systems.

技术人员解释说，脉冲相位 对于优化通信系统中的信号传输至关重要。

作文

In the realm of modern science and technology, particularly in the fields of telecommunications and signal processing, the term pulse phasing refers to the technique of adjusting the timing of signal pulses in order to achieve a desired outcome. This concept is vital for enhancing the performance and efficiency of various systems, including radar, communication networks, and even medical imaging technologies. Understanding pulse phasing can provide insights into how we manipulate signals to optimize their transmission and reception.To grasp the significance of pulse phasing, one must first understand what a pulse is in the context of signal processing. A pulse is a short burst of energy that carries information from one point to another. In digital communications, these pulses represent binary data, which is fundamental to the operation of computers and other electronic devices. However, the effective transmission of these pulses can be influenced by numerous factors, including interference, noise, and the medium through which they travel.This is where pulse phasing becomes crucial. By precisely controlling the phase of each pulse, engineers can ensure that they arrive at their destination at the right time and in the correct sequence. For example, in radar systems, pulse phasing is used to improve target detection and tracking. By adjusting the timing of the emitted pulses, radar operators can enhance the resolution of the images they receive, allowing them to distinguish between closely spaced objects more effectively.Moreover, pulse phasing also plays a significant role in medical imaging techniques such as MRI (Magnetic Resonance Imaging). In this context, the timing of radiofrequency pulses is critical for generating high-quality images of the human body. By manipulating the phase of these pulses, radiologists can enhance image contrast and resolution, leading to better diagnostic outcomes.The applications of pulse phasing extend beyond just radar and medical imaging. In telecommunications, for instance, the synchronization of pulses is essential for maintaining data integrity during transmission. When data is sent over long distances, it is susceptible to delays and distortions. By employing pulse phasing, engineers can mitigate these issues, ensuring that the received signals accurately reflect the transmitted information.In addition to its practical applications, pulse phasing also has theoretical implications in the study of wave phenomena. The principles behind pulse phasing are rooted in wave interference and superposition, where the alignment of waves can lead to constructive or destructive interference. This aspect of pulse phasing highlights the interconnectedness of various scientific disciplines, showcasing how concepts from physics can be applied to solve real-world problems.In conclusion, the concept of pulse phasing is a fundamental aspect of modern technology that impacts various fields, from telecommunications to medical imaging. By understanding and mastering pulse phasing, professionals in these industries can significantly improve the performance and reliability of their systems. As technology continues to evolve, the importance of mastering such techniques will only grow, paving the way for advancements that can transform our world.

在现代科学和技术领域，尤其是在电信和信号处理领域，术语脉冲相位调整指的是调整信号脉冲时序的技术，以实现所需的结果。这个概念对于提高各种系统的性能和效率至关重要，包括雷达、通信网络甚至医学成像技术。理解脉冲相位调整可以提供有关我们如何操控信号以优化其传输和接收的见解。要理解脉冲相位调整的重要性，首先必须了解在信号处理上下文中脉冲的含义。脉冲是传递信息的一种短暂能量爆发，从一个点到另一个点。在数字通信中，这些脉冲代表二进制数据，这是计算机和其他电子设备操作的基础。然而，这些脉冲的有效传输可能受到干扰、噪声以及它们传播介质等多种因素的影响。这就是脉冲相位调整变得至关重要的地方。通过精确控制每个脉冲的相位，工程师可以确保它们在正确的时间和顺序到达目的地。例如，在雷达系统中，脉冲相位调整用于改善目标检测和跟踪。通过调整发射脉冲的时序，雷达操作员可以增强接收到的图像分辨率，使他们能够更有效地区分紧密间隔的物体。此外，脉冲相位调整在医学成像技术（如MRI（磁共振成像））中也发挥着重要作用。在这种情况下，无线电频率脉冲的时序对生成高质量的人体图像至关重要。通过操控这些脉冲的相位，放射科医生可以增强图像的对比度和分辨率，从而改善诊断结果。脉冲相位调整的应用不仅限于雷达和医学成像。在电信领域，例如，脉冲的同步对于在传输过程中保持数据完整性至关重要。当数据通过长距离发送时，它容易受到延迟和失真。通过采用脉冲相位调整，工程师可以减轻这些问题，确保接收到的信号准确反映发送的信息。除了实际应用外，脉冲相位调整在波动现象研究中也具有理论意义。脉冲相位调整背后的原理根植于波的干涉和叠加，其中波的对齐可以导致建设性或破坏性的干涉。这一脉冲相位调整的方面突显了各种科学学科之间的相互联系，展示了物理学的概念如何应用于解决现实世界的问题。总之，脉冲相位调整的概念是现代技术的一个基本方面，影响着电信、医学成像等多个领域。通过理解和掌握脉冲相位调整，这些行业的专业人员可以显著提高其系统的性能和可靠性。随着技术的不断发展，掌握此类技术的重要性只会增加，为可以改变我们世界的进步铺平道路。