Coagulation is an essential unit in a conventional water treatment plant (WTP), of which the dosage is generally determined by jar tests and the experiences of the operators. Such an operation often results in inaccurate dosing and poor performance. In this study, back propagation artificial neural network (BPANN) was applied in the prediction of coagulant dosage. The best model of BPANN was first established from the data base containing various parameters of water quality and the corresponding optimum dosage generated from the lab-scale jar tests. The efficiency of the automatic feed-forward dosing system by BPANN was verified by a pilot-plant with conventional water treatment units targeting natural water and synthetic high turbidity water. Results of 114 jar tests were used to train, validate and test the BPANN. When the combination of LM calculation and one hidden-layer were set in the principal of early stop, all the relative coefficients (r) of prediction for various BPANN patterns edited by inputting different combinations of turbidity, pH, temperature and alkalinity of raw water exceeded 0.93. In the pilot study for the coagulations of natural water of below 100 NTU and synthetic turbidity water of around 1000 NTU, only the BPANN automatic dosing system validated by two parameters, namely, turbidity and pH, made a real-time response to predict the correct dosage for coagulation and meet the water quality standard of the WTP.