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Evaluation of Different Methods for Retrieving Temperature and Humidity Profiles in the Lower Atmosphere Using the Atmospheric Sounder Spectrometer by Infrared Spectral Technology

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Publicado en:Remote Sensing vol. 17, no. 8 (2025), p. 1440
Autor principal: Wang, Yue
Otros Autores: Xiong, Wei, Ye Hanhan, Shi Hailiang, Wang, Xianhua, Li, Chao, Wu, Shichao, Chen, Cheng
Publicado:
MDPI AG
Materias:
United States > US
Altitude
Infrared radiation
Accuracy
Humidity
Bias
Boundary layers
Radiosondes
Optimization
Atmosphere
Temperature profiles
Weather forecasting
Infrared spectrometers
Radiation measurement
Machine learning
Regularization
Physics
Fourier transforms
Thermal radiation
Ill posed problems
Spectral resolution
Damping
Retrieval
Lower atmosphere
Regularization methods
Maximum likelihood estimation
Planetary boundary layer
Acceso en línea:Citation/Abstract
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Resumen:The temperature and humidity profiles within the planetary boundary layer (PBL) are crucial for Earth’s climate research. The Atmospheric Sounder Spectrometer by Infrared Spectral Technology (ASSIST) measures downward thermal radiation in the atmosphere with high temporal and spectral resolution continuously during day and night. The physics-based retrieval method, utilizing iterative optimization, can obtain solutions that align with the true atmospheric state. However, the retrieval is typically an ill-posed problem and is affected by noise, necessitating the introduction of regularization. To achieve high-precision detection, a systematic evaluation was conducted on the retrieval performance of temperature and humidity profiles using ASSIST by regularization methods based on the Gauss–Newton framework, which include Fixed regularization factor (FR), L-Curve (LC), Generalized Cross-Validation (GCV), Maximum Likelihood Estimation (MLE), and Iterative Regularized Gauss–Newton (IRGN) methods, and the Levenberg–Marquardt (LM) method based on a damping least squares strategy. A five-day validation experiment was conducted under clear-sky conditions at the Anqing radiosonde station in China. The results indicate that for temperature profile retrieval, the IRGN method demonstrates superior performance, particularly below 1.5 <inline-formula>km</inline-formula> altitude, where the mean BIAS, mean RMSE, mean Degrees of Freedom for Signal (DFS), and mean residual reach 0.42 <inline-formula>K</inline-formula>, 0.80 <inline-formula>K</inline-formula>, 3.37, and <inline-formula>3.01×10−13</inline-formula>&#xa0;<inline-formula>W/cm2&#xa0;sr&#xa0;cm−1</inline-formula>, respectively. In contrast, other regularization methods exhibit over-regularization, leading to degraded information content. For humidity profile retrieval, below 1.5 <inline-formula>km</inline-formula> altitude, the LM method outperforms all regularization-based methods, with the mean BIAS, mean RMSE, mean DFS, and mean residual of 3.65<inline-formula>%</inline-formula>, 5.62<inline-formula>%</inline-formula>, 2.05, and <inline-formula>4.36×10−12</inline-formula>&#xa0;<inline-formula>W/cm2&#xa0;sr&#xa0;cm−1</inline-formula>, respectively. Conversely, other regularization methods exhibit strong prior dependence, causing retrieval to converge results toward the initial guess.
ISSN:2072-4292
DOI:10.3390/rs17081440
Fuente:Advanced Technologies & Aerospace Database