pulsed operation

简明释义

脉冲工捉式

英英释义

例句

1.The laser system operates in a pulsed operation, allowing for precise cutting without overheating the material.

激光系统以脉冲操作的方式运行，能够在不使材料过热的情况下进行精确切割。

2.By employing pulsed operation, the welding machine can achieve stronger joints with less heat input.

通过采用脉冲操作，焊接机可以实现更强的接头，同时减少热输入。

3.In medical applications, pulsed operation is crucial for minimizing tissue damage during procedures.

在医疗应用中，脉冲操作对于在手术过程中最小化组织损伤至关重要。

4.The radar system uses pulsed operation to detect objects at long distances effectively.

雷达系统使用脉冲操作来有效地探测远处的物体。

5.The communication system relies on pulsed operation to transmit data efficiently over long distances.

通信系统依赖于脉冲操作以高效地在长距离上传输数据。

作文

In the field of engineering and technology, the term Pulsed Operation refers to a mode of functioning where a system operates in bursts or pulses rather than continuously. This approach is widely utilized in various applications, including lasers, communication systems, and medical devices. The principle behind Pulsed Operation is to deliver energy or information in short, controlled intervals, which can lead to enhanced performance and efficiency.One of the most prominent examples of Pulsed Operation is found in laser technology. Pulsed lasers emit light in rapid bursts, allowing for precise cutting, welding, or medical procedures. For instance, in dermatology, pulsed lasers are used to treat skin conditions by delivering concentrated energy that targets specific areas without affecting the surrounding tissue. This method not only minimizes damage but also promotes faster healing times.Another significant application of Pulsed Operation is in communication systems, particularly in radar and wireless communication. In these systems, signals are transmitted in pulses, which helps in reducing interference and improving signal clarity. By using pulsed signals, the systems can better distinguish between different objects or sources of information, making them more reliable and efficient. This is crucial in environments where multiple signals may overlap, such as in urban areas with dense electronic traffic.Moreover, Pulsed Operation is also employed in medical imaging techniques like ultrasound. In ultrasound imaging, sound waves are emitted in pulses, allowing for the creation of detailed images of internal body structures. The pulsed nature of the sound waves enables healthcare professionals to obtain high-resolution images while minimizing the exposure time to patients. This technique has revolutionized prenatal care and diagnostics, providing critical information with minimal risk.The advantages of Pulsed Operation extend beyond just efficiency and precision. In many cases, operating in pulses can reduce power consumption, which is essential in today’s environmentally conscious world. For example, pulsed power systems are often more energy-efficient than their continuous counterparts. This is particularly relevant in applications where battery life is a concern, such as in portable electronic devices and remote sensors.However, implementing Pulsed Operation does come with its challenges. One of the primary concerns is the complexity of designing systems that can accurately control the timing and duration of the pulses. Engineers must ensure that the pulse duration is optimized for the specific application to achieve the desired outcomes. Additionally, the materials used in these systems must be capable of withstanding the rapid changes in energy and temperature that pulsed operation can induce.In conclusion, Pulsed Operation represents a significant advancement in various technological fields, offering numerous benefits such as increased precision, efficiency, and reduced energy consumption. As technology continues to evolve, the applications of Pulsed Operation are likely to expand, leading to innovations that can improve our daily lives. Understanding this concept is crucial for anyone involved in engineering, technology, or related fields, as it opens up new possibilities for design and functionality.

在工程和技术领域，术语脉冲操作指的是一种以脉冲或爆发的方式而非连续运行的系统工作模式。这种方法广泛应用于激光、通信系统和医疗设备等多个领域。脉冲操作背后的原理是在短时间内以受控的间隔传递能量或信息，这可以提高性能和效率。脉冲操作最显著的例子之一是在激光技术中。脉冲激光以快速爆发的方式发出光，允许进行精确的切割、焊接或医疗程序。例如，在皮肤科，脉冲激光用于治疗皮肤病，通过传递集中能量来针对特定区域，而不影响周围组织。这种方法不仅最小化了损伤，还促进了更快的愈合时间。脉冲操作的另一个重要应用是在通信系统中，特别是在雷达和无线通信中。在这些系统中，信号以脉冲的形式传输，这有助于减少干扰并提高信号清晰度。通过使用脉冲信号，系统可以更好地区分不同的物体或信息源，使其更加可靠和高效。这在多个信号可能重叠的环境中至关重要，例如在电子交通密集的城市地区。此外，脉冲操作还应用于超声等医学成像技术。在超声成像中，声波以脉冲的形式发射，从而创建内部结构的详细图像。声波的脉冲特性使医疗专业人员能够在最小风险的情况下获得高分辨率图像。这项技术彻底改变了产前护理和诊断，提供了关键的信息，风险最小。脉冲操作的优点不仅限于效率和精确性。在许多情况下，以脉冲方式操作可以减少能耗，这在当今环保意识日益增强的世界中至关重要。例如，脉冲电力系统通常比其连续对应物更节能。这在便携式电子设备和远程传感器等电池寿命至关重要的应用中尤其相关。然而，实施脉冲操作也面临挑战。主要的担忧之一是设计能够准确控制脉冲的时机和持续时间的系统的复杂性。工程师必须确保脉冲持续时间针对特定应用进行了优化，以实现所需的结果。此外，这些系统中使用的材料必须能够承受脉冲操作可能引起的能量和温度的快速变化。总之，脉冲操作代表了各个技术领域的重要进展，提供了诸多好处，如提高精度、效率和降低能耗。随着技术的不断发展，脉冲操作的应用可能会扩展，带来改善我们日常生活的创新。理解这一概念对于任何参与工程、技术或相关领域的人来说都是至关重要的，因为它为设计和功能开辟了新的可能性。