cycle-by-cycle device

简明释义

限制器限幅器

英英释义

A cycle-by-cycle device refers to a system or component that operates by analyzing and responding to each individual cycle of operation, often used in control systems to optimize performance and efficiency.

循环逐周期设备是指一种通过分析和响应每个单独操作周期来工作的系统或组件,通常用于控制系统,以优化性能和效率。

例句

1.In our latest model, the cycle-by-cycle device ensures precise control over the motor's performance.

在我们最新的型号中,逐周期设备确保对电机性能的精确控制。

2.The new power management system utilizes a cycle-by-cycle device to optimize energy consumption.

新的电源管理系统利用一个逐周期设备来优化能耗。

3.By implementing a cycle-by-cycle device, we can significantly reduce the wear and tear on machinery.

通过实施一个逐周期设备,我们可以显著减少机械的磨损。

4.The cycle-by-cycle device allows for detailed monitoring of each operational cycle.

逐周期设备允许对每个操作周期进行详细监控。

5.The engineers designed a cycle-by-cycle device that adjusts parameters in real-time for better efficiency.

工程师们设计了一个逐周期设备,实时调整参数以提高效率。

作文

In the realm of modern technology, the term cycle-by-cycle device refers to a sophisticated piece of equipment that operates by processing data or signals in discrete cycles. These devices are crucial in various applications, particularly in fields such as telecommunications, automotive systems, and robotics. Understanding how a cycle-by-cycle device functions can provide insight into its importance in contemporary engineering and technology. To elaborate, a cycle-by-cycle device typically processes inputs and produces outputs based on the information received during each cycle. This means that rather than operating continuously, these devices analyze and react to data at specific intervals. For example, in an automotive engine management system, a cycle-by-cycle device might monitor engine performance metrics like temperature, pressure, and speed every millisecond. By doing so, it can make real-time adjustments to optimize performance and efficiency.The design of a cycle-by-cycle device is often centered around the concept of feedback loops. In essence, these devices gather information from their environment, process it, and then adjust their operations accordingly. This feedback mechanism is vital for ensuring that the device remains responsive and efficient under varying conditions. For instance, in a drone's flight control system, a cycle-by-cycle device may continually assess altitude and orientation, adjusting the rotor speeds to maintain stable flight.Moreover, the implementation of cycle-by-cycle devices has revolutionized industries by enhancing precision and reliability. In manufacturing, for instance, automated assembly lines utilize these devices to monitor production quality in real time. If a defect is detected during a specific cycle, the system can immediately halt production or alert operators, thereby minimizing waste and improving overall product quality.In the field of telecommunications, cycle-by-cycle devices play a pivotal role in signal processing. They can filter, amplify, and modulate signals at high speeds, ensuring that data transmission remains clear and efficient. As the demand for faster internet speeds and more reliable connections increases, the reliance on these devices will only grow.Despite their advantages, designing a cycle-by-cycle device presents challenges. Engineers must consider factors such as timing, synchronization, and power consumption. Each cycle must be carefully calibrated to ensure that the device performs optimally without wasting energy or resources. Additionally, developers must account for potential delays that can occur between cycles, which could impact the device's responsiveness. In conclusion, the cycle-by-cycle device represents a significant advancement in technology, allowing for precise control and monitoring across various applications. As industries continue to evolve and demand higher levels of efficiency and accuracy, the importance of understanding and implementing these devices will only increase. Embracing the capabilities of cycle-by-cycle devices not only enhances operational effectiveness but also paves the way for future innovations in technology.

在现代科技领域,术语周期性设备指的是一种通过在离散周期内处理数据或信号来运行的复杂设备。这些设备在各种应用中至关重要,尤其是在电信、汽车系统和机器人等领域。理解周期性设备的工作原理可以深入了解它在当代工程和技术中的重要性。进一步说,周期性设备通常根据每个周期接收到的信息处理输入并产生输出。这意味着这些设备不是连续运行,而是在特定间隔内分析和响应数据。例如,在汽车发动机管理系统中,周期性设备可能每毫秒监测发动机性能指标,如温度、压力和速度。通过这样做,它可以实时调整以优化性能和效率。周期性设备的设计通常围绕反馈循环的概念展开。从本质上讲,这些设备从环境中收集信息,进行处理,然后相应地调整其操作。这种反馈机制对于确保设备在不同条件下保持响应和高效至关重要。例如,在无人机的飞行控制系统中,周期性设备可能不断评估高度和方向,调整旋翼转速以保持稳定飞行。此外,周期性设备的实施已经通过提高精度和可靠性彻底改变了各个行业。在制造业中,自动化装配线利用这些设备实时监控生产质量。如果在特定周期内检测到缺陷,系统可以立即停止生产或提醒操作员,从而最小化浪费,提高整体产品质量。在电信领域,周期性设备在信号处理方面发挥着关键作用。它们可以以高速过滤、放大和调制信号,确保数据传输保持清晰和高效。随着对更快互联网速度和更可靠连接的需求增加,对这些设备的依赖只会增加。尽管有其优势,但设计周期性设备也面临挑战。工程师必须考虑时间、同步和功耗等因素。每个周期必须经过仔细校准,以确保设备在不浪费能源或资源的情况下最佳运行。此外,开发人员还必须考虑周期之间可能发生的延迟,这可能影响设备的响应能力。总之,周期性设备代表了技术的一项重大进步,使各类应用能够实现精确控制和监测。随着各行业不断发展并对更高效率和准确性的需求增加,理解和实施这些设备的重要性只会增加。拥抱周期性设备的能力不仅增强了操作效率,也为未来技术创新铺平了道路。