Density functional theory (DFT), specifically Kohn--Sham DFT (KS-DFT), is a widespread method in the field of quantum computation due to its high computational efficiency. However, KS-DFT assumes the ground-state density to be non-interacting pure-state (NI-PS) v_s-representable, which limits the ability of even exact KS-DFT to handle multi-reference systems. To relieve this limitation, thermally assisted-occupation DFT (TAO-DFT) has been developed. Simulation results suggest that TAO-DFT performs similarly to KS-DFT for single-reference systems, while outperforming KS-DFT for multi-reference systems. In particular, TAO-DFT is shown to describe static correlation through fractional orbital occupations. Similar to linear-response time-dependent DFT (LR-TD-DFT) and real-time time-dependent DFT (RT-TD-DFT), LR-TD-TAO-DFT has been proposed and utilized to extract excitation energies. In this thesis, we aim to extend TAO-DFT to real-time TAO-DFT. The often made small perturbation aprroximation in LR theory is dropped for universality. The ill-defined Hartree--exchange--correlation-theta (HXCθ) action functional in the previous work is also revised. Specifically, we apply RT-TAO-DFT to hydrogen molecules. The phenomenon of high harmonic generation (HHG), which falls outside the scope of LR theory, is simulated and discussed. Simulation results suggest that RT-TAO-DFT with suitable θ performs similar to RT-TD-DFT for single-reference systems. While for multi-reference systems, RT-TAO-DFT with sufficiently large θ fixes the symmetry-breaking issue between spin-restricted and spin-unrestricted formulations.