Stereolithography is a type of additive manufacturing that uses a specific wavelength of light to cure and polymerize photocurable resin to form objects. Related technologies continue to improve the accuracy and speed of printing. However, it is technically difficult to have high printing speed, large printing area, and high accuracy at the same time. The increase in speed and area often sacrifice accuracy, and vice versa. This research is devoted to developing and improving a stereolithography system, using servo spindle motor and stepper linear actuator as the polar coordinate positioning of printed disc. Such configuration has the advantage of continuous rotation and high-speed printing, and has the potential to print large-area microstructures at high speed. The system uses Blu-ray optical pickup unit which is lost-cost, compact and has small focus spot as the light source to achieve micro-scale fabrication accuracy. In addition, in order to make the OPU laser focus stably on the surface of the base disc during printing, the system adopts dual pickup heads, which are respectively arranged above and below the base disc. The upper OPU is used as a light source for light curing. The lower OPU uses the focus error signal as a feedback reference signal, and synchronously controls the voice coil motor inside the upper and lower OPUs to make instant focus adjustments. The printing pattern is converted to polar coordinates corresponding to the position of spin printing. And control the Blu-ray switch with the decoded spindle motor encoder signal to print. The system can stably print with a maximum linear speed of 80 mm/s, a line width of about 22 μm for continuous printing, a minimum radial displacement of 1.2 μm, and a minimum angular positioning resolution of 1.25 μm. Patterns as small as 16 × 18 μm in length and width can be clearly printed with 3 μm line width. While achieving micron-level printing accuracy, it can also print patterns in the size of centimeters.