Time frequency representation is a useful technique commonly utilized in diverseelds of science and technology despite the diculty of the time-frequency uncertainty. Recently a method called the synchrosqueezing transformation has been proposed to achieve high resolution both in time and frequency. We use this method to analyze the transition amplitude obtained by solving the Schrodinger equation numerically. We take the highly nonlinear excitation of hydrogen as an example to demonstrate the usefulness of this method. When an intense laser eld (wavelength 800nm) irradiated to atoms, they are ionized through so called the tunneling ionization. Recently it is found that electronically excited states are populated as well as ionic states. This highly nonlinear excitation is understood as the key mechanism in remote lasing, or laser induced rain falling. Despite of its importance, the mechanism of excitation itself is not understood well. The purpose of this thesis is to elucidate the physical mechanism using the synchrosqueezing method. We obtained the time frequency spectra of the transition amplitude on excited states, and analyzed them using the adiabatic/nonadiabatic Floquet theory. The dynamics of the hydrogen excitation by intense laser eld is revealed as follows. As the laser is turned on, the wavefunction propagates along the adiabatic Floquet state that is smoothly connected with the initial eigen state (called the initial Floquet state). As the intensity increases, the initial Floquet state is splitted into many photon components. Around the laser peak the initial Floquet state crosses with one of the Floquet states that are smoothly connected to n = 3 eigen states (called the (n = 3)- Floquet state). An even (odd) l eigen state are populated as an even (odd) photon component in the (n = 3)-Floquet state. Nonadiabatic transition from the (n=3)-Floquet state to the Floquet state. converging to the nal eigen state determined the transition probability. An Even (odd) l state has large transition probability when the eigen energy is close to the energy of the even (odd) photon component of the (n = 3)-Floquet state.