A Comprehensive Evaluation of 4-Parameter Diurnal Temperature Cycle Models with In Situ and MODIS LST over Alpine Meadows in the Tibetan Plateau

• Published in: Remote sensing (Basel, Switzerland) Vol. 12; no. 1; p. 103
• Main Authors: Chang, Yaping, Ding, Yongjian, Zhao, Qiudong, Zhang, Shiqiang
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.01.2020
• Subjects: alpine meadow; alpine meadows; Attenuation; China; Climate change; diurnal temperature cycle model; diurnal variation; Diurnal variations; Empirical analysis; Energy; Fixing; Land cover; Land surface temperature; Mathematical models; Meadows; Meteorological satellites; Model accuracy; moderate resolution imaging spectroradiometer; MODIS; Optical thickness; Parameter sensitivity; Performance evaluation; Radiation; Regions; Remote sensing; Sensitivity analysis; Spectroradiometers; Statistical analysis; summer; Surface energy; Surface properties; surface temperature; Temperature; Temporal variations; tibetan plateau; Water balance; winter; Tibetan Plateau; China
• ISSN: 2072-4292; 2072-4292
• DOI: 10.3390/rs12010103

Diurnal variation of land surface temperature (LST) is essential for land surface energy and water balance at regional or global scale. Diurnal temperature cycle (DTC) model with least parameters and high accuracy is the key issue in estimating the spatial–temporal variation of DTC. The alpine meadow is the main land cover in the Tibetan Plateau (TP). However, few studies have been reported on the performance of different DTC models over alpine meadows in the TP. Four semi-empirical types of DTC models were used to generate nine 4-parameter (4-para) models by fixing some of free parameters. The performance of the nine 4-para DTC models were evaluated with four in situ and MODIS observations. All models except GOT09-dT-ts (dT means the temperature residual between T0 and T (t→∞); ts means the time when free attenuation begins) had higher correlation with in situ data (R2 > 0.9), while the INA08-ts model performed best with NSE of 0.99 and RMSE of 2.04 K at all sites. The GOT09-ts-τ (τ is the total optical thickness), VAN06-ts-ω1 (ω1 means the half-width of the cosine term in the morning), and GOT01-ts models had better performance, followed by GOT09-dT-τ, GOT01-dT, and VAN06-ts-ω2 (ω2 means the half-width of the cosine term in the afternoon) models. All models had higher accuracy in summer than in other seasons, while poorer performance was produced in winter. The INA08-ts model showed best performance among all seasons. Models with fixing ts could produce higher accuracy results than that with fixing dT. The comparison of INA08-ts model driven by in situ and Moderate Resolution Imaging Spectroradiometer (MODIS) data indicated that the simulation accuracy mainly depended on the accuracy of MODIS LST. The daily maximum temperature generated by the nine models had high accuracy when compared with in situ data. The sensitivity analysis indicated that the INA08-dT and GOT09-dT-ts models were more sensitive to parameter dT, while all models were insensitive to parameter ts, and all models had weak relationship with parameters ω and τ. This study provides a reference for exploring suitable DTC model in the TP.