accuracy of frequency adjustment
简明释义
频率整定精度
英英释义
The precision with which the frequency of a signal or system can be modified or tuned to achieve a desired value. | 对信号或系统的频率进行修改或调整以达到期望值的精确程度。 |
例句
1.The software update improved the accuracy of frequency adjustment, resulting in better audio performance.
软件更新提高了频率调整的准确性,从而改善了音频性能。
2.The research focused on enhancing the accuracy of frequency adjustment in radar systems.
研究集中在提高雷达系统中频率调整的准确性。
3.A high accuracy of frequency adjustment is required in medical devices to ensure proper functioning.
医疗设备需要高频率调整的准确性以确保正常运行。
4.In telecommunications, the accuracy of frequency adjustment is crucial for maintaining signal quality.
在电信领域,频率调整的准确性对于维持信号质量至关重要。
5.The engineer emphasized the accuracy of frequency adjustment in the calibration process to ensure reliable measurements.
工程师强调了校准过程中频率调整的准确性以确保测量的可靠性。
作文
In the world of technology and engineering, precision is paramount. One critical aspect that engineers often focus on is the accuracy of frequency adjustment. This term refers to the precision with which a frequency can be modified or calibrated in various devices, such as oscillators, radios, and communication systems. The significance of achieving high accuracy of frequency adjustment cannot be overstated, as it directly impacts the performance and reliability of electronic systems.To understand the importance of this concept, we must first delve into what frequency means in a technical context. Frequency, measured in hertz (Hz), indicates how often a periodic event occurs in one second. In electronics, it plays a vital role in signal processing, where different frequencies can represent different information. For instance, in radio broadcasting, various stations transmit at specific frequencies, allowing listeners to tune in to their desired channel. If the accuracy of frequency adjustment is compromised, it could lead to interference between signals, resulting in poor audio quality or even loss of transmission altogether.Moreover, the accuracy of frequency adjustment is essential in applications like GPS technology, where precise timing and frequency are crucial for accurate positioning. The satellites orbiting the Earth send signals at specific frequencies, and any deviation in these frequencies can lead to significant errors in location tracking. Therefore, engineers must ensure that the frequency adjustments made in these systems are accurate to maintain their functionality and reliability.In manufacturing, the accuracy of frequency adjustment also plays a significant role. For example, in the production of electronic components, such as quartz crystals used in watches and clocks, the frequency at which these components resonate must be precisely controlled. Any slight error in adjustment can lead to timekeeping inaccuracies, which can affect a wide range of devices from simple wristwatches to complex computer systems. Thus, maintaining a high level of accuracy of frequency adjustment is crucial in ensuring the quality of these products.Furthermore, advancements in technology have led to the development of sophisticated tools and methods for enhancing the accuracy of frequency adjustment. Techniques such as digital signal processing (DSP) and automated calibration systems have been introduced to improve the precision of frequency control. These innovations not only streamline the adjustment process but also reduce human error, which is often a significant factor in frequency inaccuracies.In conclusion, the accuracy of frequency adjustment is a fundamental aspect of modern electronics and engineering. It influences a wide array of applications, from everyday consumer electronics to advanced communication systems and navigation technologies. As our reliance on these technologies continues to grow, the need for precise frequency adjustments becomes increasingly critical. Engineers and technicians must prioritize this aspect in their work to ensure optimal performance and reliability of electronic devices. By understanding and mastering the accuracy of frequency adjustment, we can continue to innovate and enhance the technological landscape of our world.
在技术和工程的世界中,精确性至关重要。工程师们经常关注的一个关键方面是频率调整的准确性。这个术语指的是在各种设备(如振荡器、收音机和通信系统)中修改或校准频率的精度。实现高频率调整的准确性的重要性不言而喻,因为它直接影响电子系统的性能和可靠性。要理解这一概念的重要性,我们必须首先深入了解频率在技术背景下的含义。频率以赫兹(Hz)为单位,表示一个周期性事件在一秒内发生的次数。在电子学中,频率在信号处理方面发挥着至关重要的作用,不同的频率可以代表不同的信息。例如,在广播中,各个电台以特定的频率进行传输,使听众能够调到他们想要的频道。如果频率调整的准确性受到影响,可能会导致信号之间的干扰,从而导致音质差或甚至完全失去传输。因此,工程师必须确保这些系统中进行的频率调整是准确的,以保持其功能和可靠性。此外,频率调整的准确性在GPS技术等应用中也至关重要,精确的时序和频率对于准确定位至关重要。围绕地球运行的卫星以特定频率发送信号,任何频率的偏差都可能导致定位跟踪中的重大错误。因此,工程师们必须确保在这些系统中进行的频率调整是准确的,以保持其功能和可靠性。在制造业中,频率调整的准确性也发挥着重要作用。例如,在生产电子元件(如用于手表和时钟的石英晶体)时,必须精确控制这些元件共振的频率。任何微小的调整错误都可能导致计时不准确,从而影响从简单的手表到复杂的计算机系统的广泛设备。因此,保持高水平的频率调整的准确性对于确保这些产品的质量至关重要。此外,技术的进步导致了增强频率调整的准确性的复杂工具和方法的发展。数字信号处理(DSP)和自动校准系统等技术的引入提高了频率控制的精度。这些创新不仅简化了调整过程,还减少了人为错误,这通常是频率不准确的重要因素。总之,频率调整的准确性是现代电子学和工程学的基本方面。它影响着从日常消费电子产品到先进的通信系统和导航技术的广泛应用。随着我们对这些技术的依赖不断增长,对精确频率调整的需求变得越来越重要。工程师和技术人员必须在工作中优先考虑这一方面,以确保电子设备的最佳性能和可靠性。通过理解和掌握频率调整的准确性,我们可以继续创新并增强我们世界的技术格局。
相关单词
