In situ NMR measurements of the diffusion coefficients,including an estimate of signal strength,of lithium ion conductor using diffusion-weighting pulse sequence are performed in this study.A cascade bilinear model is proposed to estimate the diffusion sensitivity factors of pulsed-field gradient using prior information of the electrochemical performance and Arrhenius constraint.The model postulates that the active lithium nuclei participating electrochemical reaction are relevant to the NMR signal intensity,when discharge rate or temperature condition is varying.The electrochemical data and the NMR signal strength show a highly fit with the proposed model according our simulation and experiments.Furthermore,the diffusion time is constrained by temperature based on Arrhenius equation of reaction rates dependence.An experimental calculation of Li_4Ti_5O_(12)(LTO)/carbon nanotubes(CNTs) with the electrolyte evaluating at 20 ℃ is presented,which the b factor is estimated by the discharge rate. In situ NMR measurements of the diffusion coefficients, including an estimate of signal strength, of lithium ion conductor using diffusion-weighting pulse sequences are performed in this study. A cascade bilinear model is proposed to estimate the diffusion sensitivity factors of pulsed-field gradient using prior information of the electrochemical performance and Arrhenius constraint. The model postulates that the active lithium nuclei participating electrochemical reaction are relevant to the NMR signal intensity, when discharge rate or temperature condition is varying. electrochemical data and the NMR signal strength show a highly fit with the proposed model according our simulation and experiments. Ferdinandmore, the diffusion time is constrained by temperature based on Arrhenius equation of reaction rates dependence. An experimental calculation of Li_4Ti_5O_ (12) (LTO) / carbon nanotubes (CNTs) with the electrolyte evaluating at 20 ℃ is presented, which the b factor is estimated by the discharg e rate.