We employed a cavity ringdown spectrometer with a tunable infrared OPO/OPA laser with a bandwidth of 0.02 cm-1 to record the absorption spectra of methylperoxy radicals (CH3OO) in the range 2930-3050 cm-1. Methylperoxy radicals were produced by irradiating a flowing mixture of CH3I and O2 with emission at 248 nm from a KrF excimer laser or a flowing mixture of CH3C(O)CH3 and O2 with emission at 193 nm from an ArF excimer laser. Two absorption bands with origins at 2953.4 cm-1 and 3020.7 cm-1 were observed; they are assigned to ν2 (symmetric CH3 stretching) and ν9 (antisymmetric CH2 stretching) modes of CH3OO, respectively. We analyzed the rotational structures of the ν2 and ν9 bands by simply treating CH3OO as a prolate symmetric top, and determined the rotational constants both in the ground state and in the vibrationally excited state. We predicted vibrational wavenumbers and rotational parameters for the upper and lower vibrational states, and the mixing ratio among a-, b-, c-types of bands of CH3OO with the B3LYP/aug-cc-pVTZ density-functional theory. The rotational contours for the ν1, ν2 and ν9 bands of CH3OO were simulated with the SpecView software. For the ν2 band, the simulation agrees satisfactorily with the experimental observations except for the intense peaks with regular spacing about 2.4 cm-1 in the range 2940-2950 cm-1. For the ν9 band, the simulation result is consistent with the experimental observations in the region 3000-3020 cm-1 but not in the region 3020-3050 cm-1. The discrepancy might be due to the interference from the ν1 band. That ν1 band is unobserved is likely due to its relatively small intensity. We temporarily assigned the ν1 band to be at 3031.7 cm-1 by matching the simulated spectra with the peaks which do not correspond to the ν9 band.