pulse manipulated

简明释义

脉冲操作的

英英释义

例句

1.In medical imaging, pulse manipulated sequences improve the clarity of the images.

在医学成像中，脉冲调制序列提高了图像的清晰度。

2.The research team discovered that pulse manipulated techniques can optimize energy consumption in devices.

研究小组发现，脉冲调制技术可以优化设备的能源消耗。

3.By using pulse manipulated signals, the radar system can detect smaller objects more effectively.

通过使用脉冲调制信号，雷达系统可以更有效地探测到较小的物体。

4.Engineers are experimenting with pulse manipulated lasers for precision cutting.

工程师们正在试验用于精密切割的脉冲调制激光。

5.The device uses a technique where the pulse manipulated signals can enhance communication quality.

该设备使用一种技术，其中脉冲调制信号可以增强通信质量。

作文

In the realm of modern technology and medicine, the term pulse manipulated refers to a technique that involves altering the characteristics of a pulse signal to achieve desired outcomes. This concept is particularly significant in fields such as telecommunications, medical diagnostics, and even in therapeutic applications. Understanding how pulse manipulated signals work can provide insights into their practical uses and implications for future innovations.To begin with, let's explore what a pulse is. In simple terms, a pulse is a sudden change in signal strength or voltage that occurs over a short period. These pulses can carry information, and by manipulating them, we can enhance communication systems or improve medical treatments. For instance, in telecommunications, pulse manipulated signals are used to encode information for transmission over various media, allowing for clearer and more efficient communication.Furthermore, in the medical field, pulse manipulated techniques are employed in therapies such as ultrasound and electrical stimulation. In these applications, specific pulse patterns are generated and adjusted to target certain tissues or organs, promoting healing or diagnostic imaging. For example, during an ultrasound procedure, the frequency and duration of sound waves are pulse manipulated to create images of internal body structures, aiding in the diagnosis of various conditions.Moreover, the ability to manipulate pulse signals has led to groundbreaking advancements in brain-computer interfaces (BCIs). By pulse manipulated brain signals, researchers can develop systems that allow individuals to control devices using their thoughts. This technology holds promise for people with disabilities, enabling them to interact with their environment in ways previously thought impossible.The process of pulse manipulated can involve various techniques, including modulation, encoding, and filtering. Modulation refers to the method of varying a carrier signal in order to transmit data effectively. This can include amplitude modulation (AM), frequency modulation (FM), and phase modulation (PM). Each of these methods allows for different types of information to be encoded within a pulse, making it possible to tailor communications to specific needs.In addition, pulse manipulated signals can also be filtered to eliminate noise and enhance clarity. In both telecommunications and medical applications, filtering ensures that the intended signal stands out against background noise, thereby improving the quality of the transmitted information or the accuracy of diagnostic results.As technology continues to evolve, the potential applications of pulse manipulated signals are vast. Researchers are exploring new ways to harness this technique to improve not only communication systems but also medical treatments, energy transfer, and even environmental monitoring. The versatility of pulse manipulated technology makes it a critical area of study for engineers and scientists alike.In conclusion, the concept of pulse manipulated represents a fascinating intersection of technology and science. By understanding how to effectively manipulate pulse signals, we can unlock new possibilities in communication, medicine, and beyond. As we continue to advance in these fields, the implications of pulse manipulated techniques will undoubtedly shape the future of innovation, enhancing our ability to connect, heal, and understand the world around us.

在现代科技和医学领域，术语脉冲操控指的是一种技术，它涉及到改变脉冲信号的特征以实现所需的结果。这个概念在电信、医疗诊断甚至治疗应用等领域都具有重要意义。理解脉冲操控信号的工作原理可以为其实际用途和未来创新的影响提供见解。首先，让我们探讨什么是脉冲。简单来说，脉冲是信号强度或电压在短时间内的突然变化。这些脉冲可以携带信息，通过操控它们，我们可以增强通信系统或改善医疗治疗。例如，在电信中，脉冲操控信号用于对信息进行编码，以便通过各种媒介传输，从而实现更清晰、更高效的通信。此外，在医疗领域，脉冲操控技术被应用于超声波和电刺激等疗法。在这些应用中，生成并调整特定的脉冲模式以针对某些组织或器官，促进愈合或诊断成像。例如，在超声检查过程中，声波的频率和持续时间被脉冲操控以创建内部身体结构的图像，帮助诊断各种病症。此外，操控脉冲信号的能力已经导致脑-机接口（BCI）领域的突破性进展。通过脉冲操控脑信号，研究人员可以开发出允许个体通过思维控制设备的系统。这项技术为残疾人士带来了希望，使他们能够以前所未有的方式与环境互动。脉冲操控的过程可以涉及多种技术，包括调制、编码和过滤。调制是指改变载波信号以有效传输数据的方法。这可以包括幅度调制（AM）、频率调制（FM）和相位调制（PM）。每种方法都允许在脉冲中编码不同类型的信息，从而使通信能够针对特定需求进行定制。此外，脉冲操控信号也可以过滤，以消除噪声并增强清晰度。在电信和医疗应用中，过滤确保了预期信号在背景噪声中脱颖而出，从而提高了传输信息的质量或诊断结果的准确性。随着技术的不断发展，脉冲操控信号的潜在应用是广泛的。研究人员正在探索利用这种技术来改善通信系统、医疗治疗、能量传输甚至环境监测的新方法。脉冲操控技术的多功能性使其成为工程师和科学家研究的关键领域。总之，脉冲操控的概念代表了技术和科学的一个迷人交汇点。通过理解如何有效地操控脉冲信号，我们可以解锁通信、医学及其他领域的新可能性。随着我们在这些领域的不断进步，脉冲操控技术的影响无疑将塑造创新的未来，增强我们连接、治疗和理解周围世界的能力。