The optical profilometer is a powerful instrument for measuring the surface morphology, which has been widely utilized in many different applications such as precise mechanical components, MEMS, membranes, and medical devices. Comparing with the contact profilometer, the optical profilometer doesn't need a stylus to contact with the sample. Therefore, it has advantages such as high speed, sample protection and no cost for the stylus. The astigmatic optical profilometer uses a DVD pick-up head as a core measurement component, and the focus error signal can be used to measure the surface structure at nanoscale. The astigmatic optical profilometer has advantages of high speed, high resolution, and compact size. However, the focus error signal is affected by the surface reflectivity significantly. Therefore, a calibration procedure is required for each sample with reflectivities. Moreover, the quantitative measurement can not be obtained on a sample consisting of complex materials. To solve this problem, two operation modes called the Z-axis feedback control mode and the Z-axis scanning mode were proposed in this thesis. An astigmatic optical profilometer system and a height calculation program were developed. Two stardard samples (CS-20NG and R2L2S1N1) were measured in the experiments. The experimental results show that the 20 nm height structures on CS-20NG can be measured quantitatively. The results on R2L2S1N1 show that the Z-axis scanning mode can achieve quantitative height measurement on the surface consisting of two materials with different reflectivities. Furthermore, the surface reflectivity can also be imaged in the Z-axis scanning mode.