delay characteristic

简明释义

延迟特性

英英释义

例句

1.The engineer analyzed the delay characteristic of the circuit to improve its performance.

工程师分析了电路的延迟特性以提高其性能。

2.The delay characteristic of the system was measured to ensure it met the required standards.

系统的延迟特性被测量以确保符合要求的标准。

3.The report detailed the delay characteristic of various algorithms used in data processing.

报告详细说明了用于数据处理的各种算法的延迟特性。

4.In telecommunications, the delay characteristic is crucial for maintaining call quality.

在电信中，延迟特性对于保持通话质量至关重要。

5.Understanding the delay characteristic of a network can help in optimizing data transmission.

理解网络的延迟特性有助于优化数据传输。

作文

In the realm of engineering and signal processing, the term delay characteristic refers to the response time of a system or component when it processes an input signal. Understanding the delay characteristic is crucial for designing efficient systems, especially in fields such as telecommunications, audio processing, and control systems. A system with a well-defined delay characteristic can effectively manage the timing of signals, ensuring that they are transmitted and received without significant lag or distortion.When we talk about delay in a system, we often refer to the time taken for an input signal to produce an output signal. This delay can be influenced by various factors, including the physical properties of the materials used, the configuration of the system, and external environmental conditions. For instance, in digital communication, if the delay characteristic is not properly accounted for, it can lead to issues such as data loss or miscommunication between devices.One of the most common examples of delay characteristic can be observed in audio processing systems. When sound is captured, processed, and played back, any delay in the system can result in echoes or phase issues, leading to a poor listening experience. Audio engineers must carefully analyze the delay characteristic of their equipment to ensure that the sound is reproduced accurately and in real-time. This requires precise calibration and sometimes even the use of advanced algorithms to compensate for any inherent delays in the system.Moreover, in control systems, understanding the delay characteristic is vital for maintaining stability. In a feedback loop, any delay in the response can cause oscillations or instability, which can be detrimental in applications such as robotics or automated manufacturing. Engineers must take into account the delay characteristic when designing controllers to ensure that the system reacts appropriately to changes in input.In telecommunications, the delay characteristic plays a significant role in determining the quality of service. For example, in video conferencing applications, excessive delay can lead to awkward pauses and interruptions, making communication difficult. Network engineers strive to minimize latency and optimize the delay characteristic of their networks to provide seamless experiences for users. This often involves a combination of hardware optimization, software solutions, and strategic routing of data packets.Understanding the delay characteristic is also essential in the development of new technologies. As we move towards faster and more efficient systems, engineers are constantly looking for ways to reduce delays and enhance performance. Innovations in materials science, algorithm design, and system architecture all contribute to improving the delay characteristic of various applications.In conclusion, the concept of delay characteristic is integral to many fields, particularly those involving signal processing and system design. By comprehensively understanding and managing the delay characteristic, engineers can create more effective, reliable, and user-friendly systems. Whether in audio processing, telecommunications, or control systems, the ability to analyze and optimize delay characteristics is a key skill that contributes to the advancement of technology. As we continue to innovate and push the boundaries of what is possible, the importance of mastering the delay characteristic will only grow in significance.

在工程和信号处理领域，术语延迟特性指的是系统或组件在处理输入信号时的响应时间。理解延迟特性对于设计高效的系统至关重要，特别是在电信、音频处理和控制系统等领域。具有良好定义的延迟特性的系统可以有效管理信号的时序，确保信号在没有显著延迟或失真的情况下传输和接收。当我们谈论系统中的延迟时，通常是指输入信号产生输出信号所需的时间。这种延迟可能受到多种因素的影响，包括所用材料的物理特性、系统的配置以及外部环境条件。例如，在数字通信中，如果未正确考虑延迟特性，可能会导致数据丢失或设备之间的误通信。延迟特性的一个最常见示例可以在音频处理系统中观察到。当声音被捕获、处理和播放时，系统中的任何延迟都可能导致回声或相位问题，从而导致糟糕的听觉体验。音频工程师必须仔细分析其设备的延迟特性，以确保声音被准确且实时地再现。这需要精确的校准，有时甚至需要使用先进的算法来补偿系统中固有的延迟。此外，在控制系统中，理解延迟特性对于保持稳定性至关重要。在反馈回路中，响应中的任何延迟都可能导致振荡或不稳定，这在机器人技术或自动化制造等应用中可能是有害的。工程师在设计控制器时必须考虑延迟特性，以确保系统能够适当地对输入变化做出反应。在电信领域，延迟特性在决定服务质量方面发挥着重要作用。例如，在视频会议应用中，过度延迟可能导致尴尬的停顿和中断，使沟通变得困难。网络工程师努力最小化延迟并优化其网络的延迟特性，以为用户提供无缝体验。这通常涉及硬件优化、软件解决方案和数据包的战略路由的组合。理解延迟特性在新技术的发展中也至关重要。随着我们朝着更快、更高效的系统迈进，工程师们不断寻找减少延迟和增强性能的方法。材料科学、算法设计和系统架构的创新都为改善各种应用的延迟特性做出了贡献。总之，延迟特性的概念与许多领域密切相关，尤其是涉及信号处理和系统设计的领域。通过全面理解和管理延迟特性，工程师可以创建更有效、可靠和用户友好的系统。无论是在音频处理、电信还是控制系统中，分析和优化延迟特性的能力都是推动技术进步的关键技能。随着我们继续创新并推动可能性的边界，掌握延迟特性的重要性只会越来越突出。