resultant pitch

简明释义

合成节距

英英释义

例句

1.For the new product, we need to analyze the resultant pitch after adjusting the dimensions.

对于新产品，我们需要在调整尺寸后分析结果螺距。

2.During the design of the gear system, the team had to determine the resultant pitch to optimize performance.

在齿轮系统的设计过程中，团队必须确定结果螺距以优化性能。

3.The engineer calculated the resultant pitch of the screw to ensure it would fit properly in the assembly.

工程师计算了螺钉的结果螺距以确保它能正确安装在组件中。

4.In music theory, the resultant pitch can be described as the frequency produced by the combination of multiple tones.

在音乐理论中，结果音高可以被描述为多个音调组合产生的频率。

5.The resultant pitch of the notes played together created a harmonious sound.

一起演奏的音符的结果音高产生了和谐的声音。

作文

In the realm of music, understanding the concept of pitch is essential for both musicians and listeners alike. Pitch refers to the perceived frequency of a sound, determining how high or low it sounds to us. However, when we delve deeper into the intricacies of sound, we encounter the term resultant pitch, which plays a significant role in how we perceive complex sounds. The resultant pitch (结果音高) is the pitch that we hear when multiple frequencies are played simultaneously. This phenomenon occurs frequently in music, where different instruments or voices combine their sounds to create a harmonious blend. To illustrate this, consider a simple example of two musical notes being played together. If a piano plays a middle C (approximately 261.63 Hz) and an E above it (approximately 329.63 Hz), the resultant pitch (结果音高) we perceive is not merely the individual pitches of C and E but rather a new pitch that emerges from the combination of these frequencies. This new pitch can evoke different emotions and feelings, adding depth to the musical experience.The science behind resultant pitch (结果音高) lies in the way our auditory system processes sound waves. When two or more frequencies are played together, our brain interprets these sounds in a way that often results in a perceived pitch that may not correspond directly to any of the original frequencies. This is particularly evident in the use of harmonics and overtones in music, where the combination of fundamental frequencies gives rise to richer, fuller sounds.Furthermore, the concept of resultant pitch (结果音高) extends beyond music into other areas such as acoustics and sound engineering. For instance, in the design of concert halls, acousticians must consider how various frequencies interact within the space to ensure that audiences receive a clear and pleasant auditory experience. The resultant pitches produced by the reflections and reverberations in the hall can significantly affect the quality of sound that reaches the listener's ears.In addition to its applications in music and acoustics, the idea of resultant pitch (结果音高) can also be observed in everyday life. For example, when we hear the sound of a busy street with cars honking, people talking, and sirens wailing, we are experiencing a complex mixture of sounds. Our brains work tirelessly to decipher these overlapping frequencies, and what we ultimately perceive is a series of resultant pitches that convey the bustling atmosphere of the city.In conclusion, the concept of resultant pitch (结果音高) is a fascinating aspect of sound perception that highlights the complexity of auditory experiences. Whether in music, architectural acoustics, or everyday life, the way in which multiple frequencies combine to create new pitches enriches our auditory landscape. Understanding this concept not only enhances our appreciation of music but also deepens our awareness of the intricate world of sound that surrounds us. As we continue to explore the realms of sound and music, the study of resultant pitch (结果音高) will undoubtedly remain a vital area of interest for musicians, scientists, and enthusiasts alike.

在音乐领域，理解音高的概念对音乐家和听众来说都是至关重要的。音高是指声音的感知频率，决定了我们听到的声音是高还是低。然而，当我们深入探讨声音的复杂性时，我们会遇到“结果音高”这一术语，它在我们感知复杂声音的过程中发挥着重要作用。结果音高 (结果音高) 是指当多个频率同时播放时，我们所听到的音高。这种现象在音乐中经常发生，不同的乐器或声音结合在一起，创造出和谐的音色。为了说明这一点，考虑一个简单的例子：两个音符同时演奏。如果一架钢琴演奏中音C（大约261.63赫兹）和其上的E（大约329.63赫兹），我们所感知的结果音高 (结果音高) 并不仅仅是C和E的单独音高，而是从这些频率的组合中产生的新音高。这种新音高可以唤起不同的情感和感觉，为音乐体验增添深度。结果音高 (结果音高) 背后的科学原理在于我们的听觉系统如何处理声波。当两个或多个频率同时播放时，我们的大脑以一种方式解释这些声音，通常导致感知的音高可能与任何原始频率不直接对应。这在音乐中的泛音和谐波的使用中特别明显，其中基本频率的组合产生更丰富、更饱满的声音。此外，结果音高 (结果音高) 的概念不仅限于音乐，还扩展到其他领域，如声学和音响工程。例如，在音乐厅的设计中，声学家必须考虑各种频率在空间中的相互作用，以确保观众获得清晰和愉悦的听觉体验。音乐厅内反射和混响产生的结果音高 (结果音高) 可以显著影响听众耳中传来的声音质量。除了在音乐和声学中的应用外，结果音高 (结果音高) 的概念也可以在日常生活中观察到。例如，当我们听到繁忙街道上的汽车鸣笛、人们交谈和警笛声时，我们正在经历复杂的声音混合。我们的脑海努力解读这些重叠的频率，最终我们感知到的是一系列的结果音高 (结果音高)，传达了城市的繁忙氛围。总之，结果音高 (结果音高) 的概念是声音感知的一个迷人方面，突显了听觉体验的复杂性。无论是在音乐、建筑声学，还是日常生活中，多种频率的组合创造出新的音高，丰富了我们的听觉景观。理解这一概念不仅增强了我们对音乐的欣赏，也加深了我们对环绕我们复杂声音世界的认识。随着我们继续探索声音和音乐的领域，结果音高 (结果音高) 的研究无疑将继续成为音乐家、科学家和爱好者的重要关注领域。