Intense field excitation of molecule is a key mechanism in various applications of laser fillamentation. In the previous studies, it has been found that the excitation probabilities have power dependences with large powers. In the case of 800nm, oxygen molecule and hydrogen atom have two groups with different powers, whereas the methane has one group with a common power. It was not clearly understood the reson for the difference. Using the time-frequency analysis, it has been understood the reason why the parity of the angular momentum quantum number determines the excitation behaviors. In this study taking the H2+ molecule as as example, we examine the reson for the difference of one group and two group behaviors. In this case the ionization potential is about 3 times larger than hydrogen atom. In such a case transition mechanism is complicated and many Floquet states couples complicatedly. This leads to the unclear symmetry dependence in the excitation behavior. Futhermore the number of photons needed to excite to highly lying states is large because of the large ionization potential. Therefore excitation needs a large laser intensity, leading to a large nonadiabatic transition probabilities. The population created on an adiabatic Floquet state is redistributed widely in energy. This is why we find only one group in the case of 800nm with H2+ molecule. On the other hand with the 600nm laser, the number of photons needed is smaller than 800nm case. In this case the population created around the laser peak is not redistributed widely in energy. This is why we find two groups depending on whether the energy level of the final state is close to the photon dressed ground state. Our analysis is expected to reveal the reason why methane has one group, and oxygen molecule has two groups, or what determines the groups in the case of oxygen molecule.