现代精准农业要求采集随时空变化而变化的海量土壤肥力信息，虽然传统化学分析法发挥了重大作用，但由于投入大而难以满足现代农业生产的需求，而原子光谱法则为土壤肥力信息的快速获取提供了可能手段。本研究将利用激光诱导击穿技术，优化配置高功率和双光束激光光源，以我国不同时空分布的典型农田土壤样本为材料，获得土壤原子光谱，分析测定的影响因素 (样本制备方法、波段范围、分辨率、扫描位点和激光烧蚀深度等)，率先构建土壤原子光谱的测定方法；然后利用高斯函数和数据转换 (小波分析和反卷积)，对土壤原子光谱进行前处理，以减少系统环境干扰和样本基体效应，获取代表性的高信噪比土壤原子光谱；进而分析我国典型农田土壤的原子光谱特征，综合利用主成分分析、偏最小二乘法回归和人工神经网络等数学工具进行光谱建模，提取目标土壤肥力信息，并从原子组成的角度解析土壤肥力形成和演变特征，为土壤肥力评估提及土壤数字化提供理论支撑。

The mass information about soil fertility, varied in time and in space, is required for modern precision agriculture. Although the conventional chemical analysis method has played a major role in the soil fertility evaluation, but it seems difficult to meet the needs of modern agricultural production due to too large input, and the technique of atomic spectroscopy provides an alternative option for the fast acquisition of soil fertility. Laser induced breakdown technology will be involved in this study, and the light source will be optimized by high power laser and dual beam. Then the typical farmland soils with temporal and spatial variation from all over China will be collected for the atomic spectra recording. The factors affecting the determination of soil atomic spectra, including sample preparation method, spectral range, resolution, scanning sites and laser ablation depth, will be investigated and optimized, and the determination method of soil atomic spectra will be built in the first time. The obtained soil atomic spectra will be treated by Gauss function and data conversion (wavelet analysis and deconvolution), so as to reduce the interference of environmental noise and sample matrix, and obtain representative soil atomic spectra with high ratio of signal to noise. Based on above results, typical farmland soils will be characterized by soil atomic spectra, integrated utilization of mathematical tools, i.e. principal component analysis, partial least squares regression and artificial neural network, will be made for spectral modeling, and the target information about soil fertility will be separated; then the attempts will be initiated for elucidating the mechanism of the formation and evolution of soil fertility from the level of atomic composition, which will provide theoretical support for fast soil fertility evaluation and soil digitalization.