Development of a new particle imaging radiosonde with particle fall velocity measurements in clouds

IF 1.7 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Sola Pub Date : 2023-01-01 DOI:10.2151/sola.2023-034

Kenji Suzuki, Yurika Hara, Takuji Sugidachi, Kensaku Shimizu, Masatomo Fujiwara

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Abstract

A new particle imaging radiosonde “Rainscope” has been developed, and for the first time, particle fall velocity measurement functionality was added to a balloon-borne device. Rainscope can capture a clear still image of precipitation particles in a cloud when they interrupt an infrared beam, using a CMOS camera equipped with an electronic shutter. It can also record the time when a particle passes the upper and lower built-in infrared sensors, enabling measurement of the velocity of falling precipitation particles. For ground testing in rain and snow, a ground-based Rainscope showed raindrop/snowflake size-fall velocity distributions similar to those obtained in previous studies. In a comparison with a Parsivel2 disdrometer in rain, the Rainscope results were in good agreement with the distributions obtained by an adjacent Parsivel2. In a test flight of Rainscope into a stratiform cloud, raindrops, mostly melted particles, snowflakes in the process of melting, graupel, and snowflakes were observed. It was observed that the fall velocity varied depending on the type of solid precipitation particles.

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一种新型粒子成像无线电探空仪的研制，可测量粒子在云层中的下落速度

一种新的粒子成像无线电探空仪“Rainscope”已经开发出来，并且首次将粒子下落速度测量功能添加到气球载设备中。当云层中的降水粒子干扰红外光束时，雨镜可以使用配备电子快门的CMOS相机捕捉到清晰的静止图像。它还可以记录粒子通过上下内置红外传感器的时间，从而测量降水粒子下落的速度。在雨雪条件下的地面测试中，地面雨镜显示的雨滴/雪花大小下降速度分布与之前的研究结果相似。在雨中与Parsivel2分差仪比较，Rainscope的结果与相邻Parsivel2分差仪的分布吻合较好。在Rainscope进入层状云的一次试飞中，观测到了雨滴，大部分是融化的颗粒，融化过程中的雪花，霰和雪花。结果表明，固体沉降颗粒的类型不同，沉降速度也不同。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Sola 地学-气象与大气科学

CiteScore

3.50

自引率

21.10%

发文量

审稿时长

>12 weeks

期刊介绍： SOLA (Scientific Online Letters on the Atmosphere) is a peer-reviewed, Open Access, online-only journal. It publishes scientific discoveries and advances in understanding in meteorology, climatology, the atmospheric sciences and related interdisciplinary areas. SOLA focuses on presenting new and scientifically rigorous observations, experiments, data analyses, numerical modeling, data assimilation, and technical developments as quickly as possible. It achieves this via rapid peer review and publication of research letters, published as Regular Articles. Published and supported by the Meteorological Society of Japan, the journal follows strong research and publication ethics principles. Most manuscripts receive a first decision within one month and a decision upon resubmission within a further month. Accepted articles are then quickly published on the journal’s website, where they are easily accessible to our broad audience.