rawinsonde
简明释义
英[ˈreɪwɪnsɒnd]美[ˈreɪwɪnˌsɑːnd]
n. 雷达气球;[气象] 无线电探空测风仪
英英释义
单词用法
探空气球网络 | |
实时探空气球 | |
探空气球剖面 | |
探空气球上升 | |
探空气球发射地点 | |
探空气球风剖面 | |
探空气球温度读数 | |
探空气球湿度测量 |
同义词
| 气象气球 | The weather balloon was launched to collect upper-atmospheric data. | 气象气球被发射以收集高层大气数据。 | |
| 气象探测 | Meteorological soundings are essential for accurate weather forecasting. | 气象探测对于准确的天气预报至关重要。 |
反义词
例句
1.Then cloud motion winds are derived from these tracers and after a circumfluence analysis on the cloud motion winds, the cloud motion winds are compared with the rawinsonde winds.
对用该方法选取的示踪云进行云迹风 反演,然后对 反演出的云迹 风进行环流分析,并与探空 风进行比较。
2.Then cloud motion winds are derived from these tracers and after a circumfluence analysis on the cloud motion winds, the cloud motion winds are compared with the rawinsonde winds.
对用该方法选取的示踪云进行云迹风 反演,然后对 反演出的云迹 风进行环流分析,并与探空 风进行比较。
3.Meteorologists use a rawinsonde to gather data on atmospheric conditions.
气象学家使用原始探空仪来收集大气条件的数据。
4.During the storm, a rawinsonde was launched to track wind speeds.
在暴风雨期间,发射了一台原始探空仪来跟踪风速。
5.The data collected by the rawinsonde helps in predicting severe weather events.
由原始探空仪收集的数据有助于预测严重天气事件。
6.A rawinsonde can measure temperature, humidity, and pressure at various altitudes.
原始探空仪可以测量不同高度的温度、湿度和气压。
7.The rawinsonde is essential for understanding weather patterns.
原始探空仪对于理解天气模式至关重要。
作文
In the field of meteorology, understanding weather patterns is crucial for predicting climate changes and ensuring public safety. One essential tool in this endeavor is the rawinsonde, which plays a significant role in gathering atmospheric data. A rawinsonde (原始探空仪) is an instrument used to measure various atmospheric parameters such as temperature, humidity, pressure, and wind speed at different altitudes. This data is vital for meteorologists to create accurate weather forecasts and study atmospheric phenomena.The operation of a rawinsonde involves attaching the instrument to a weather balloon filled with helium or hydrogen. As the balloon ascends into the atmosphere, the rawinsonde transmits real-time data back to ground stations via radio signals. The ascent typically reaches altitudes of up to 30 kilometers, allowing for comprehensive data collection from the troposphere to the lower stratosphere. This vertical profiling of the atmosphere is essential for understanding how weather systems develop and evolve.One of the key advantages of using a rawinsonde is its ability to provide three-dimensional data on wind patterns. By measuring wind direction and speed at various altitudes, meteorologists can better understand the dynamics of storm systems, jet streams, and other atmospheric phenomena. This information is critical for predicting severe weather events, such as hurricanes and tornadoes, which can have devastating impacts on communities.Moreover, the data collected by rawinsonde instruments are not only useful for short-term weather forecasting but also for long-term climate studies. By analyzing historical rawinsonde data, scientists can identify trends in temperature and humidity changes over time, contributing to our understanding of climate change. This research is essential for developing strategies to mitigate the impacts of global warming and for preparing for future climate-related challenges.In recent years, advancements in technology have enhanced the capabilities of rawinsonde systems. Modern instruments are now equipped with GPS technology, allowing for more precise tracking of the balloon's position and altitude. This improvement enables meteorologists to obtain even more accurate data on atmospheric conditions. Additionally, new materials and designs have made rawinsonde balloons more durable and capable of reaching higher altitudes, further expanding the range of data that can be collected.Despite these advancements, the use of rawinsonde is not without challenges. For instance, the launch of rawinsonde balloons requires careful planning and coordination, as they can pose risks to aviation if not managed properly. Furthermore, the cost of producing and deploying rawinsonde systems can be significant, particularly for smaller meteorological organizations.In conclusion, the rawinsonde (原始探空仪) is an indispensable tool in the field of meteorology, providing crucial data for weather forecasting and climate research. Its ability to collect comprehensive atmospheric data makes it a vital resource for understanding our planet's weather systems. As technology continues to advance, the potential for rawinsonde instruments to contribute to meteorological science will only grow, helping us to better prepare for the challenges posed by an ever-changing climate.
在气象学领域,理解天气模式对于预测气候变化和确保公众安全至关重要。rawinsonde(原始探空仪)是这一努力中不可或缺的工具,它在收集大气数据方面发挥着重要作用。rawinsonde 是一种用于测量温度、湿度、压力和不同高度风速等各种大气参数的仪器。这些数据对于气象学家创建准确的天气预报和研究大气现象至关重要。rawinsonde 的操作涉及将仪器附加到充满氦气或氢气的气象气球上。随着气球升入大气层,rawinsonde 通过无线电信号实时传输数据回到地面站。上升通常可达到30公里的高度,从而允许从对流层到下层平流层全面收集数据。这种大气的垂直剖面对于理解天气系统的发展和演变至关重要。使用rawinsonde 的一个主要优点是它能够提供关于风模式的三维数据。通过测量不同高度的风向和风速,气象学家可以更好地理解风暴系统、急流和其他大气现象的动态。这些信息对于预测严重天气事件,如飓风和龙卷风至关重要,因为这些事件可能对社区造成毁灭性的影响。此外,rawinsonde 收集的数据不仅对短期天气预报有用,而且对长期气候研究也很重要。通过分析历史rawinsonde 数据,科学家可以识别温度和湿度变化的趋势,从而有助于我们理解气候变化。这项研究对于制定减缓全球变暖影响的策略以及为未来气候相关挑战做准备至关重要。近年来,技术的进步增强了rawinsonde 系统的能力。现代仪器现在配备了GPS技术,使气球的位置和高度的跟踪更加精确。这一改进使气象学家能够获得更准确的大气条件数据。此外,新材料和设计使得rawinsonde 气球更加耐用,能够达到更高的高度,进一步扩展了可以收集的数据范围。尽管有这些进步,使用rawinsonde 也并非没有挑战。例如,发射rawinsonde 气球需要仔细规划和协调,因为如果管理不当,它们可能对航空安全构成风险。此外,生产和部署rawinsonde 系统的成本可能相当高,特别是对于较小的气象组织而言。总之,rawinsonde(原始探空仪)是气象学领域中不可或缺的工具,为天气预报和气候研究提供了至关重要的数据。它收集全面大气数据的能力使其成为理解我们星球天气系统的重要资源。随着技术的不断进步,rawinsonde 仪器为气象科学作出贡献的潜力只会不断增长,帮助我们更好地应对日益变化的气候带来的挑战。
