amplitude uniformity

简明释义

振幅一致性;

英英释义

例句

1.The quality control team measured the amplitude uniformity 幅度均匀性 of the produced waves to ensure they met industry standards.

质量控制团队测量了生产波的amplitude uniformity 幅度均匀性，以确保它们符合行业标准。

2.In our latest project, we focused on achieving amplitude uniformity 幅度均匀性 in the lighting design.

在我们最新的项目中，我们专注于实现照明设计中的amplitude uniformity 幅度均匀性。

3.The research focused on the amplitude uniformity 幅度均匀性 of signals in wireless communication systems.

研究集中在无线通信系统中信号的amplitude uniformity 幅度均匀性上。

4.For accurate acoustic measurements, amplitude uniformity 幅度均匀性 is crucial in the testing environment.

对于准确的声学测量，测试环境中的amplitude uniformity 幅度均匀性至关重要。

5.The engineers tested the sound system to ensure its amplitude uniformity 幅度均匀性 across different frequencies.

工程师们测试了音响系统，以确保其在不同频率下的amplitude uniformity 幅度均匀性。

作文

In various fields of science and engineering, the concept of amplitude uniformity plays a crucial role in ensuring the accuracy and reliability of measurements and signals. Amplitude uniformity (幅度均匀性) refers to the consistency of the amplitude of a signal across different points or conditions. This is particularly important in areas such as telecommunications, audio engineering, and medical imaging, where variations in amplitude can lead to significant errors or distortions.For instance, in telecommunications, maintaining amplitude uniformity is vital for clear signal transmission. If the amplitude of a transmitted signal fluctuates, it can result in poor reception or loss of data. Engineers work diligently to design systems that minimize these fluctuations, ensuring that the amplitude remains consistent throughout the transmission process. This not only enhances the quality of communication but also improves the overall efficiency of the network.Similarly, in audio engineering, amplitude uniformity is essential for producing high-quality sound. When recording music, sound engineers aim to achieve a uniform amplitude across different tracks and instruments. If one instrument has a significantly higher or lower amplitude than others, it can create an unbalanced mix, detracting from the overall listening experience. By utilizing tools such as compressors and limiters, engineers can ensure that the amplitude of each track is balanced, resulting in a more harmonious final product.In the realm of medical imaging, amplitude uniformity is critical for accurate diagnostics. For example, in ultrasound imaging, variations in amplitude can affect the clarity of the images produced. If the amplitude is not uniform, it can lead to misinterpretations of the images, potentially resulting in incorrect diagnoses. Therefore, medical professionals rely on advanced imaging technologies that prioritize amplitude uniformity to ensure that the images are as clear and accurate as possible.Achieving amplitude uniformity often involves rigorous testing and calibration processes. In many cases, specialized equipment is used to measure the amplitude of signals and identify any inconsistencies. Once these discrepancies are detected, engineers and technicians can implement corrective measures, such as adjusting the gain or using filtering techniques, to restore uniformity.Moreover, the importance of amplitude uniformity extends beyond just technical applications; it also has implications for research and development. In experimental settings, researchers must ensure that their measurements maintain amplitude uniformity to draw valid conclusions from their data. Any variation in amplitude could introduce biases or errors, leading to flawed results and potentially hindering scientific progress.In conclusion, amplitude uniformity is a fundamental concept that underpins many technological and scientific advancements. Whether in telecommunications, audio engineering, or medical imaging, the need for consistent amplitude is paramount. By prioritizing amplitude uniformity, professionals in these fields can enhance the quality and reliability of their work, ultimately benefiting society as a whole. As technology continues to evolve, the significance of maintaining uniformity in amplitude will undoubtedly remain a key focus for researchers and engineers alike.

在科学和工程的各个领域，幅度均匀性的概念在确保测量和信号的准确性和可靠性方面发挥着至关重要的作用。幅度均匀性指的是信号在不同点或条件下幅度的一致性。这在电信、音频工程和医学成像等领域尤为重要，因为幅度的变化可能导致显著的错误或失真。例如，在电信中，保持幅度均匀性对于清晰的信号传输至关重要。如果传输信号的幅度波动，可能会导致接收不良或数据丢失。工程师们努力设计系统，以最小化这些波动，确保幅度在整个传输过程中保持一致。这不仅提高了通信质量，还改善了网络的整体效率。同样，在音频工程中，幅度均匀性对于制作高质量声音至关重要。在录制音乐时，声音工程师旨在实现不同轨道和乐器之间的幅度均匀性。如果某个乐器的幅度明显高于或低于其他乐器，则可能会造成不平衡的混音，影响整体听觉体验。通过使用压缩器和限制器等工具，工程师可以确保每个轨道的幅度保持平衡，从而产生更和谐的最终产品。在医学成像领域，幅度均匀性对准确诊断至关重要。例如，在超声成像中，幅度的变化会影响所产生图像的清晰度。如果幅度不均匀，可能会导致对图像的误解，从而可能导致错误诊断。因此，医疗专业人员依赖于优先考虑幅度均匀性的先进成像技术，以确保图像尽可能清晰和准确。实现幅度均匀性通常涉及严格的测试和校准过程。在许多情况下，使用专用设备来测量信号的幅度并识别任何不一致之处。一旦发现这些差异，工程师和技术人员可以采取纠正措施，例如调整增益或使用过滤技术，以恢复均匀性。此外，幅度均匀性的重要性不仅限于技术应用；它还对研究和开发有影响。在实验环境中，研究人员必须确保他们的测量保持幅度均匀性，以便从数据中得出有效的结论。幅度的任何变化都可能引入偏差或错误，导致结果出现缺陷，并可能阻碍科学进步。总之，幅度均匀性是许多技术和科学进步的基础概念。无论是在电信、音频工程还是医学成像中，保持一致的幅度都是至关重要的。通过优先考虑幅度均匀性，这些领域的专业人士可以提高其工作的质量和可靠性，最终使整个社会受益。随着技术的不断发展，保持幅度均匀性的重要性无疑将继续成为研究人员和工程师的重点。