wave form

简明释义

控制电压波形

英英释义

例句

1.To troubleshoot the circuit, the technician examined the wave form of the output signal.

为了解决电路问题，技术人员检查了输出信号的wave form。

2.In physics class, we learned how to graph a wave form to represent sound waves.

在物理课上，我们学习了如何绘制wave form来表示声波。

3.The audio engineer analyzed the wave form to identify any distortions in the recording.

音频工程师分析了wave form以识别录音中的任何失真。

4.The music software allows you to edit the wave form directly for precise sound manipulation.

该音乐软件允许您直接编辑wave form以进行精确的声音处理。

5.The wave form displayed on the oscilloscope showed a clear sine wave.

示波器上显示的wave form呈现出清晰的正弦波。

作文

In the realm of physics and engineering, the concept of wave form plays a crucial role in understanding how waves behave and interact with different mediums. A wave form can be described as the shape or pattern of a wave, which is characterized by its amplitude, frequency, wavelength, and phase. These attributes not only define the visual representation of a wave but also determine how it propagates through space and time.When we talk about sound waves, for instance, the wave form is essential for analyzing audio signals. Different instruments produce distinct wave forms, which contribute to their unique sounds. For example, a piano generates a waveform that is quite different from that of a guitar, even if they play the same note. This difference is due to the harmonic content and the way the sound waves are generated and shaped by each instrument.In electronics, engineers often use oscilloscopes to visualize the wave form of electrical signals. By observing the wave form, they can diagnose issues in circuits and ensure that devices function correctly. A clean, periodic wave form indicates a stable signal, while irregularities may suggest interference or malfunctioning components. Thus, understanding wave forms is essential for troubleshooting and improving electronic systems.Moreover, in telecommunications, wave forms are utilized to encode and transmit information over various media. Modulation techniques, such as amplitude modulation (AM) and frequency modulation (FM), alter the wave form of a carrier signal to convey messages. The ability to manipulate wave forms enables efficient communication across vast distances, allowing for everything from radio broadcasts to mobile phone conversations.In the field of medicine, particularly in medical imaging and diagnostics, wave forms are significant. For instance, electrocardiograms (ECGs) display the wave form of electrical activity in the heart. Physicians analyze these wave forms to detect abnormalities in heart function, making it an invaluable tool for patient care. Similarly, ultrasound technology relies on wave forms to create images of internal body structures, demonstrating how versatile and critical wave forms are across different fields.As technology continues to advance, the study and application of wave forms are becoming increasingly sophisticated. Researchers are exploring new ways to manipulate wave forms for various applications, including improving data transmission rates and enhancing imaging techniques. The future of wave form analysis holds exciting possibilities, especially with the emergence of quantum computing and advanced materials that can affect wave propagation.In conclusion, the concept of wave form is fundamental to many scientific and engineering disciplines. Its implications stretch across sound, electronics, telecommunications, and medicine, showcasing the importance of understanding how waves behave and interact. By mastering the intricacies of wave forms, we can harness their power to innovate and improve technology, ultimately enhancing our daily lives. Therefore, whether in a classroom or a laboratory, the study of wave forms remains a vital pursuit for anyone interested in the sciences or engineering.

在物理和工程领域，wave form（波形）的概念在理解波动如何行为及与不同介质相互作用中扮演着至关重要的角色。wave form可以被描述为波的形状或模式，其特征由振幅、频率、波长和相位决定。这些属性不仅定义了波的视觉表现，还决定了它如何在空间和时间中传播。例如，当我们谈论声波时，wave form对于分析音频信号至关重要。不同的乐器产生不同的wave forms，这为它们独特的声音贡献力量。例如，钢琴产生的波形与吉他产生的波形截然不同，即使它们演奏同一个音符。这种差异源于谐波成分以及每种乐器生成和塑造声波的方式。在电子学中，工程师通常使用示波器来可视化电信号的wave form。通过观察wave form，他们可以诊断电路中的问题，并确保设备正常运行。干净的周期性wave form表明信号稳定，而不规则性可能表明干扰或故障组件。因此，理解wave forms对于故障排除和改善电子系统至关重要。此外，在电信中，wave forms被用于编码和传输各种媒体上的信息。调制技术，如幅度调制（AM）和频率调制（FM），通过改变载波信号的wave form来传达消息。操控wave forms的能力使得跨越广阔距离的高效通信成为可能，从而实现从广播到手机通话的所有功能。在医学领域，特别是在医学成像和诊断中，wave forms也非常重要。例如，心电图（ECG）显示了心脏电活动的wave form。医生分析这些wave forms以检测心脏功能的异常，使其成为患者护理不可或缺的工具。类似地，超声技术依赖于wave forms创建内部结构的图像，证明了wave forms在不同领域的多样性和重要性。随着技术的不断进步，wave forms的研究和应用变得越来越复杂。研究人员正在探索操控wave forms的新方法，以用于各种应用，包括提高数据传输速率和增强成像技术。wave form分析的未来充满了令人兴奋的可能性，尤其是在量子计算和先进材料等新兴领域，这些材料能够影响波的传播。总之，wave form的概念是许多科学和工程学科的基础。其影响跨越声音、电子学、电信和医学，展示了理解波动如何行为及相互作用的重要性。通过掌握wave forms的复杂性，我们可以利用其力量进行创新和技术改进，最终提升我们的日常生活。因此，无论是在教室还是实验室，学习wave forms仍然是任何对科学或工程感兴趣的人必不可少的追求。