Spectral quantitative analysis of complex samples based on extreme learning machine
writer:Xihui Bian*, Shujuan Li, Mengran Fan, Yugao Guo, Na Chang, Jiangjiang
keywords:Extreme learning machine, Multivariate calibration, Spectral quantitative analysis, Complex samples
source:期刊
specific source:Analytical Methods, 2016, 8 (23): 4674-4679
Issue time:2016年
Multivariate calibration including linear and non-linear methods has been widely used in the spectral
quantitative analysis of complex samples. Despite the efficiency and few parameters
involved, linear methods are inferior for nonlinear problems. Non-linear
methods also have disadvantages such as requirement many parameters,
time-consuming and easily relapsing into local optima though the outstanding
performance in nonlinearity. Thus, taking the advantages of both linear and non-linear
methods, a novel algorithm called extreme learning machine (ELM) is introduced.
The efficiency and stability of the method are investigated firstly. Then the optimal
activation function and number of hidden layer nodes are determined by a new defined
parameter, which took into account both predictive accuracy and stability of
the model. The predictive performance of ELM is compared
with principal component regression (PCR), partial least squares (PLS), support vector regression (SVR) and back propagation artificial neural
network (BP-ANN) by three near-infrared (NIR) spectral datasets of diesel fuel,
ternary mixture and blood. Results show that the efficiency of ELM is mainly
affected by the number of nodes for a certain dataset. Despite some
instability, ELM becomes stable close to the optimal parameters. Moreover, ELM
has better or comparable performance compared with its competitors in the spectral
quantitative analysis of complex samples.