line flyback

简明释义

水平回描

英英释义

例句

1.To optimize the performance, we need to adjust the line flyback parameters.

为了优化性能，我们需要调整线性飞回参数。

2.The technician explained how to implement the line flyback in the circuit design.

技术员解释了如何在电路设计中实现线性飞回。

3.In high-frequency applications, managing line flyback is crucial for reducing noise.

在高频应用中，管理线性飞回对减少噪声至关重要。

4.The engineer demonstrated the effects of line flyback on signal integrity.

工程师演示了线性飞回对信号完整性的影响。

5.During the troubleshooting process, we discovered that the line flyback was causing interference.

在故障排除过程中，我们发现线性飞回导致了干扰。

作文

In the world of electronics and telecommunications, various terms and concepts are crucial for understanding how devices operate. One such term is line flyback, which refers to a specific type of signal or method used in the transmission of information. Essentially, line flyback (行回波) describes the process where a signal returns along the same path after reaching its destination. This concept is particularly important in the context of cathode ray tube (CRT) displays and other similar technologies. The line flyback mechanism is integral to the functioning of CRTs, where it allows the electron beam to return to the starting point after completing one line of scanning. This return journey is essential for refreshing the display and ensuring that images are rendered correctly. Without the line flyback process, screens would not be able to maintain a stable image, leading to flickering and distortion.Moreover, the line flyback technique can also be observed in various types of data transmission systems. In these systems, signals may need to be sent back to their original source for error checking or synchronization purposes. By utilizing the line flyback method, systems can efficiently manage signal integrity and reduce latency, which is critical for real-time communication applications.Understanding line flyback also opens up discussions about its implications on technology design and innovation. Engineers and designers must account for this phenomenon when creating devices that rely on signal transmission. For example, the efficiency of a device can be significantly impacted by how well it implements the line flyback process. Poor execution might lead to increased power consumption or reduced performance, which are undesirable outcomes in modern electronics.Furthermore, exploring the broader applications of line flyback can lead to advancements in fields like video technology, telecommunications, and even computer graphics. As technology continues to evolve, the principles underlying line flyback may inspire new methods for improving data transmission and enhancing visual displays. Researchers are constantly seeking ways to refine these processes, aiming for better resolution and faster refresh rates in displays.In conclusion, the term line flyback encapsulates a fundamental aspect of signal processing in electronics. Its importance cannot be overstated, as it plays a vital role in ensuring the functionality and efficiency of various devices. Understanding this concept not only aids in grasping how certain technologies work but also encourages further exploration into innovations that could arise from refining these principles. As we move forward in the digital age, the relevance of line flyback will likely continue to grow, shaping the future of electronics and communication technologies.

在电子和电信的世界中，各种术语和概念对于理解设备的运作至关重要。一个这样的术语是行回波，它指的是在信息传输中使用的一种特定类型的信号或方法。基本上，行回波（line flyback）描述了信号在到达目的地后沿同一路径返回的过程。这个概念在阴极射线管（CRT）显示器和其他类似技术的背景下尤为重要。行回波机制是CRT正常工作的关键，它允许电子束在完成一行扫描后返回起始点。这一返回旅程对刷新显示屏至关重要，并确保图像正确渲染。如果没有行回波过程，屏幕将无法保持稳定的图像，导致闪烁和失真。此外，在各种数据传输系统中也可以观察到行回波技术。在这些系统中，信号可能需要返回其原始源进行错误检查或同步。通过利用行回波方法，系统可以有效管理信号完整性并减少延迟，这对于实时通信应用至关重要。理解行回波也引发了关于其对技术设计和创新影响的讨论。工程师和设计师在创建依赖信号传输的设备时必须考虑这一现象。例如，设备的效率可能会受到如何良好实施行回波过程的显著影响。执行不当可能导致功耗增加或性能下降，这在现代电子设备中是不可取的结果。此外，探索行回波的更广泛应用可能会推动视频技术、电信甚至计算机图形学等领域的进步。随着技术的不断发展，支撑行回波的原理可能会激发改进数据传输和增强视觉显示的新方法。研究人员不断寻求改进这些过程的方法，以期在显示器中获得更好的分辨率和更快的刷新率。总之，术语行回波概括了电子信号处理的基本方面。它的重要性不容小觑，因为它在确保各种设备的功能和效率方面发挥着至关重要的作用。理解这一概念不仅有助于掌握某些技术的工作方式，还鼓励进一步探索可能从完善这些原则中产生的创新。随着我们在数字时代的前进，行回波的相关性可能会继续增长，塑造电子和通信技术的未来。