2026-05-15 合肥物質科学研究院(HFIPS)
Time series of daily mean CO2 column concentrations from MM-LHRNet and NLSM. Circles denote the daily mean values. Shaded bands indicate mean ± 1σ (Image by XIONG Hao).
<関連情報>
- https://english.hf.cas.cn/nr/rn/202605/t20260515_1159457.html
- https://www.sciencedirect.com/science/article/abs/pii/S0925400526005514
レーザーヘテロダイン放射測定法を用いた高精度二酸化炭素カラムセンシングのためのマルチモーダルニューラル融合 Multi-modal neural fusion for accurate carbon dioxide column sensing using laser heterodyne radiometry
Hao Xiong, Zhao Chen, Chunyan Sun, Guishi Wang, Kun Liu, Xiaoming Gao
Sensors and Actuators B: Chemical Available online: 14 April 2026
DOI:https://doi.org/10.1016/j.snb.2026.139973
Highlights
- A novel multimodal neural fusion network is proposed for laser heterodyne sensing.
- The method eliminates dependence on a priori concentration profiles.
- A CO₂ column relative precision of approximately 0.11% is achieved.
- Retrieval speed is improved by more than three orders of magnitude.
Abstract
Laser heterodyne radiometer (LHR) provides high spectral resolution and compact size for atmospheric greenhouse gas column sensing, yet traditional fully physical retrieval algorithms are limited by high computational cost and strong dependence on prior concentration profiles. To address these limitations, we propose a novel multimodal neural network (MM-LHRNet) for CO2 column retrieval based on LHR observations. In atmospheric CO2 monitoring experiments conducted in Hefei, China, the proposed method achieved a standard deviation of 0.49 ppm (corresponding to an precision of approximately 0.11%), significantly outperforming the 1.09 ppm (corresponding to an precision of approximately 0.25%) obtained using the traditional nonlinear least-squares method (NLSM). Furthermore, MM-LHRNet eliminates the need for CO2 prior concentration profiles and improves retrieval speed by more than three orders of magnitude, substantially reducing computational costs. Experimental results show that MM-LHRNet provides a high-precision and efficient retrieval strategy for LHR-based greenhouse gas column measurements, and further offers a novel technical pathway for future real-time atmospheric greenhouse gas retrieval.
