wavegoing performance

简明释义

波浪中航行性能

英英释义

例句

1.Engineers are focusing on enhancing the wavegoing performance of the vessel for better navigation.

工程师们专注于提升船只的波浪行驶性能以改善导航。

2.The yacht's wavegoing performance was tested in various sea conditions.

这艘游艇的波浪行驶性能在不同的海况下进行了测试。

3.The study revealed that the wavegoing performance is crucial for competitive sailing.

研究显示，波浪行驶性能对竞技帆船非常重要。

4.Her experience in rough waters improved her wavegoing performance significantly.

她在恶劣水域的经历显著提升了她的波浪行驶性能。

5.The new surfboard design greatly improved the wavegoing performance of beginners.

新的冲浪板设计大大提高了初学者的波浪行驶性能。

作文

In recent years, the concept of wavegoing performance has gained significant attention in various fields, particularly in engineering and environmental sciences. Understanding this term is crucial for anyone involved in the study of wave dynamics, whether it be in oceanography, acoustics, or even in the design of structures that interact with waves. wavegoing performance refers to the ability of a system or structure to effectively respond to and manage the energy carried by waves. This can include how well a vessel navigates through ocean waves, how buildings withstand wind-induced vibrations, or how sound waves are transmitted through different media.For instance, in naval architecture, the wavegoing performance of a ship is evaluated based on its stability, speed, and comfort while sailing in rough seas. Designers strive to create hull shapes that minimize resistance and maximize efficiency, ensuring that vessels can travel safely and quickly across turbulent waters. A ship with excellent wavegoing performance will not only provide a smoother ride for passengers but will also consume less fuel, making it more environmentally friendly.Similarly, in civil engineering, understanding wavegoing performance is vital when constructing buildings in coastal areas or regions prone to strong winds. Engineers must consider how wind and wave forces will act on a structure, designing it to withstand potential damage. By analyzing the wavegoing performance of a building, engineers can ensure that it remains safe and functional during extreme weather events, thus protecting both the structure and its occupants.Moreover, the concept of wavegoing performance extends beyond physical structures to encompass various technologies. In telecommunications, for example, the wavegoing performance of signal transmission systems is critical. The efficiency with which data is transmitted over wireless networks can be significantly influenced by the characteristics of the waves used for communication. By optimizing the wavegoing performance of these systems, we can achieve faster and more reliable connections, which are essential in today's digital age.Understanding the implications of wavegoing performance is not limited to technical fields; it also has broader environmental impacts. For instance, researchers studying ocean waves and their interactions with marine ecosystems are increasingly focusing on wavegoing performance. By understanding how waves influence sediment transport and nutrient distribution, scientists can better assess the health of marine environments and develop strategies for conservation.In conclusion, the term wavegoing performance encapsulates a wide range of applications across different disciplines. Whether in engineering, telecommunications, or environmental science, recognizing the significance of wavegoing performance allows professionals to make informed decisions that enhance safety, efficiency, and sustainability. As we continue to face challenges related to climate change and resource management, understanding and improving wavegoing performance will undoubtedly play a crucial role in shaping our future.

近年来，“wavegoing performance”这一概念在多个领域引起了广泛关注，特别是在工程学和环境科学中。理解这个术语对于任何从事波动动态研究的人来说都是至关重要的，无论是在海洋学、声学，还是在与波浪相互作用的结构设计中。“wavegoing performance”指的是一个系统或结构有效响应和管理波浪所携带能量的能力。这可以包括一艘船如何在海浪中航行、建筑物如何承受风引起的振动，或者声音波如何通过不同介质传播。例如，在船舶设计中，一艘船的“wavegoing performance”是根据其在恶劣海况下的稳定性、速度和舒适度来评估的。设计师努力创造出可以最小化阻力并最大化效率的船体形状，以确保船只能够安全快速地穿越动荡水域。一艘具有优秀“wavegoing performance”的船不仅能为乘客提供更平稳的航行体验，还能消耗更少的燃料，从而更加环保。同样，在土木工程中，理解“wavegoing performance”在沿海地区或强风区域建造建筑物时至关重要。工程师必须考虑风和波浪对结构的作用力，设计其能承受潜在的损害。通过分析建筑物的“wavegoing performance”，工程师可以确保其在极端天气事件中保持安全和功能，从而保护结构及其居住者。此外，“wavegoing performance”这一概念不仅限于物理结构，还涵盖了各种技术。例如，在电信领域，信号传输系统的“wavegoing performance”至关重要。数据在无线网络中的传输效率可能会受到用于通信的波特性的显著影响。通过优化这些系统的“wavegoing performance”，我们可以实现更快、更可靠的连接，这在当今数字时代至关重要。理解“wavegoing performance”的意义不仅限于技术领域，它还具有更广泛的环境影响。例如，研究海洋波浪及其与海洋生态系统相互作用的研究人员越来越关注“wavegoing performance”。通过了解波浪如何影响沉积物运输和营养物质分布，科学家们可以更好地评估海洋环境的健康状况，并制定保护策略。总之，“wavegoing performance”这一术语涵盖了不同学科的广泛应用。无论是在工程、通讯还是环境科学中，认识到“wavegoing performance”的重要性使专业人士能够做出明智的决策，从而提高安全性、效率和可持续性。随着我们继续面临气候变化和资源管理相关的挑战，理解和改善“wavegoing performance”无疑将在塑造我们的未来中发挥关键作用。