bit skew

简明释义

钻头偏转量;

英英释义

例句

1.High-speed interfaces are particularly sensitive to bit skew due to their timing requirements.

由于高速接口的时序要求，它们对比特偏移尤其敏感。

2.The design team implemented measures to correct bit skew in the new PCB layout.

设计团队在新的PCB布局中实施了纠正比特偏移的措施。

3.The circuit experienced a significant bit skew, causing data corruption during transmission.

该电路经历了显著的比特偏移，导致传输过程中数据损坏。

4.During the testing phase, we observed that bit skew was affecting the timing of the signals.

在测试阶段，我们观察到比特偏移影响了信号的时序。

5.To improve performance, we need to minimize bit skew in our signal paths.

为了提高性能，我们需要最小化信号路径中的比特偏移。

作文

In the world of digital communication and data transmission, precision is paramount. One of the critical aspects that engineers and technicians must consider is the alignment of bits in a data stream. This is where the term bit skew comes into play. Bit skew refers to the timing difference between individual bits in a data signal. It can occur due to various factors, such as variations in the physical lengths of the transmission paths or differences in the speed at which signals travel through different media. When bit skew occurs, it can lead to misinterpretation of data, resulting in errors during data processing or transmission.To understand the implications of bit skew, we must first recognize how digital data is transmitted. Digital signals are composed of bits, which are the fundamental units of information in computing and telecommunications. These bits are transmitted sequentially over a medium, and their correct alignment is crucial for accurate data interpretation. If the bits arrive at their destination out of sync, it can cause significant issues.For example, consider a scenario in which a computer sends a series of bits representing a message to another computer. If the first few bits arrive on time, but subsequent bits experience delays due to bit skew, the receiving computer may interpret the message incorrectly. This misalignment can lead to corrupted data, software crashes, or even security vulnerabilities if the data is sensitive.The challenges posed by bit skew are particularly evident in high-speed data transmission systems. As the speed of data transfer increases, the tolerance for timing discrepancies decreases. Engineers must design systems that can either minimize bit skew or compensate for it effectively. Techniques such as using equal-length transmission paths, implementing advanced error detection and correction algorithms, and employing synchronization protocols are commonly used to address this issue.Moreover, modern technologies like fiber optics and wireless communication have introduced new challenges related to bit skew. In fiber optic systems, for instance, light signals travel at incredibly high speeds, and any delay in a single bit can disrupt the entire communication process. Similarly, in wireless networks, environmental factors such as interference can exacerbate bit skew, leading to increased latency and reduced data integrity.In conclusion, understanding bit skew is essential for anyone involved in the fields of computer science, telecommunications, or data engineering. The ability to recognize and mitigate the effects of bit skew can significantly enhance the reliability and efficiency of data transmission systems. As technology continues to advance, the importance of addressing bit skew will only grow, making it a critical area of focus for future innovations in digital communication.

在数字通信和数据传输的世界中，精确性至关重要。工程师和技术人员必须考虑的一个关键方面是数据流中比特的对齐。这就是术语bit skew的由来。bit skew指的是数据信号中各个比特之间的时间差。这可能由于多种因素而发生，例如传输路径物理长度的变化或信号通过不同介质传播速度的差异。当发生bit skew时，可能导致数据的误解，从而在数据处理或传输过程中出现错误。要理解bit skew的影响，我们首先必须认识到数字数据是如何传输的。数字信号由比特组成，比特是计算和电信中信息的基本单位。这些比特按顺序通过介质传输，其正确的对齐对于准确的数据解释至关重要。如果比特在到达目的地时不同步，可能会导致重大问题。例如，考虑一种场景，其中一台计算机向另一台计算机发送一系列表示消息的比特。如果前几个比特准时到达，但后续比特由于bit skew而延迟到达，那么接收计算机可能会错误地解释该消息。这种不对齐可能导致数据损坏、软件崩溃，甚至如果数据敏感，可能导致安全漏洞。bit skew带来的挑战在高速数据传输系统中尤为明显。随着数据传输速度的提高，对时序差异的容忍度降低。工程师必须设计能够最小化bit skew或有效补偿它的系统。常用的技术包括使用等长传输路径、实施先进的错误检测和纠正算法，以及采用同步协议来解决这个问题。此外，现代技术如光纤和无线通信也引入了与bit skew相关的新挑战。在光纤系统中，例如，光信号以极高的速度传播，单个比特的任何延迟都可能干扰整个通信过程。同样，在无线网络中，环境因素如干扰可能加剧bit skew，导致延迟增加和数据完整性降低。总之，理解bit skew对任何参与计算机科学、电信或数据工程领域的人来说都是至关重要的。识别和减轻bit skew影响的能力可以显著提升数据传输系统的可靠性和效率。随着技术的不断进步，解决bit skew的重要性只会增加，使其成为未来数字通信创新的关键关注领域。