A new polymerase chain reaction (PCR) machine is developed for discussing the optical sensor selection and analyzing the fluorescence data in this study. The goal is to achieve low cost and high accuracy. In the future, we hope to popularize this machine at clinics for immediate disease detection. General PCR nucleic acid amplification test must be controlled to the three temperature, which are 95℃, 60℃and72℃. This machine combines two technologies that are capillary convective polymerase chain reaction (CCPCR)and Real-time polymerase chain reaction(Real-time PCR). By single temperature control, the capillary will be heated to 95℃. Then, observing the change of fluorescence intensity in a capillary continuously when the reagent in the tube reaches the desired three temperatures by natural convection. Finally, Nucleic acid amplification completed within 30 minutes. At the first, this study replace the reagent container from a glass capillary cost 25NTD to a plastic capillary cost lower than 1NTD. This change greatly reduce the cost of tubes. However, compared to plastic and glass, the transmittance decreased by approximately 40%, so the optical sensors must be improved. This research used a nickel-chromium wire as a heater for CCPCR. The copper block is heated to temperature 95℃ fixedly by the nickel-chromium wire at the bottom of the capillary and the temperature standard deviation is 0.2℃. About the optical mechanism, blue light-emitting diodes (LED) is used to light the capillary from below and collect the fluorescence signal from the side. This study selects three kinds of optical sensors to experiment, namely color sensor, silicon detector and webcam. Sensitivity test with nucleic acid of HBV initial concentration of 50 copies/tube was amplified successfully. Repeatability test with three kinds of concentration of 5×105copies/tube, 5×103copies/tube and 5×101copies/tube was plot fluorescence curves. By curve fitting, we can draw the standard curve of this CCPCR machine to find the initial concentration of virus.