Core Insights - The "Extreme Eye No. 1" airship successfully conducted atmospheric observation tests in the Lulang area of Tibet, achieving a significant technological leap from single-point sampling to three-dimensional monitoring [1][3] - The airship carried 16 scientific payloads with a total weight of approximately 200 kilograms, reaching an altitude of 5,500 meters, providing essential data for research on the Tibetan Plateau [1] Group 1 - The airship, also known as a tethered balloon, serves as an aerial "scientific testing platform" controlled by a cable anchored to the ground [1] - The project, led by the Chinese Academy of Sciences' Aerospace Information Innovation Research Institute, has completed 30 flight verifications since August, collecting critical data on atmospheric components, pollutant distribution, and cloud microphysical parameters [3] - The airship has been involved in systematic scientific observations in various regions of the Tibetan Plateau since 2017, contributing to the understanding of climate change and sustainable development [3] Group 2 - The experiment aims to investigate the relationship between clouds and rainfall, addressing the challenges in weather forecasting accuracy due to insufficient parameterization in cloud-rainfall simulation [3] - A unique "electrocardiogram-style" scanning method was designed to capture changes in microphysical characteristics throughout the cloud lifecycle, supporting improvements in simulation models [3]

Core Insights - The successful test of the "Extreme Eye No. 1" airship in Tibet marks a significant advancement in atmospheric observation technology, providing essential data for research on the Tibetan Plateau and global climate change [1][2] Group 1: Test Details - The test involved 16 scientific payloads with a total weight of approximately 200 kilograms, reaching an altitude of 5,500 meters [1] - The airship completed 30 flight validations from August to September 19, successfully collecting critical scientific data on atmospheric components, pollutant distribution, and cloud microphysical parameters [1] Group 2: Technological Advancements - The airship, also known as a tethered balloon, serves as an aerial "scientific testing platform" controlled by a cable anchored to the ground [1] - The design of the cloud "electrocardiogram" scanning during the test allows for the observation of microphysical characteristics throughout the cloud lifecycle, aiding in the improvement of weather simulation models [2] Group 3: Research Implications - The data collected will support dynamic monitoring and sustainable development in the "Asian Water Tower" and other climate-sensitive areas [1] - The airship has been involved in systematic scientific observations in various regions of the Tibetan Plateau since 2017, contributing to ongoing climate research [2]