In this thesis, we replaced the traditional photolithography process with a simple way to fabricate a PDLC-Based Tunable Diaphragm. We used the characteristic of the Polymer-Dispersed Liquid Crystal (PDLC) to tune the diaphragm. Driving PDLC with different voltage result in different transmittance to define the bright and dark region of the diaphragm. In the design, the diaphragm structure is formed by two piece of Indium Tin Oxide (ITO) conductive glass and some Polyethylene Terephthalate (PET) film as spacer. Simultaneously, we dripped NOA65 optical adhesive into a circular area between the two ITO glass and exposed with the UV light to solidify the NOA65. We prepared PDLC with a specific weight ratio of E7 liquid crystal to NOA65 polymer. Fill in the prepared PDLC by capillary phenomenon and exposed with the UV light. A diaphragm which its center area is transparent and the other area is milky white will be done. By the same way as above, we dripped different volume of NOA65 to fabricate diaphragms of different diameter. Finally, we stacked the diaphragms in sequence and the assembled diaphragms could be tuned by changing its electrodes. After fabricating the diaphragm device, we stuck up the copper wires with some conductive silver paste to extend the electrodes. Moreover, we designed a black case to package the device by 3D printing which its material is Polylactic Acid (PLA) in order to set up in a camera more convenient. At last, we did some measurement and analysis on the device.