Technology Innovation Award for his %u201cdynamic virgin fruit fly classifier with time-varying characteristics%u201d.%u2605 Technology implementation: (1)The image monitoring process results developed with TSMC have been expanded for application in TSMC factories; (2)Continued development of intelligent manufacturing technology with Delta Electronics, combining artificial intelligence with image processing and deep learning technology, making substantial contributions to the domestic Industry 4.0 and intelligent manufacturing fields.%u25a0 Advanced material process research includes carbon/composite materials, field emission characteristics, and hand-held atmospheric plasma generators.%u2605 Proposed a novel pre-treatment method to break through the difficulty of growing diamonds on anodized aluminum, and further developed a self-assembled chemical vapor deposition system to grow nano-diamond tip arrays. For the first time, diamonds were successfully grown on alumina materials. A uniform hole structure with a pore diameter of 20 nm and a spacing of 30 nm was obtained through process parameter design. In addition, for the first time, a diamond nanotip array with a curvature of a quadrangular pyramid structure was obtained using an anodized aluminum barrier layer as a template, and it was found that this structure can suppress the field emission shielding effect.%u2605 Developed a hand-held atmospheric plasma generator, including self-developed carbon nanotube/alumina doublelayer sheets as the cathode of the plasma generator, and proposed a small, safe atmospheric plasma generator that includes a water-cooling system. Plasma can be generated in the atmospheric environment.%u25a0 Research on the laser manufacturing process and microstructure manufacturing process. Because the femtosecond laser pulse is extremely short, it has a cold processing effect; in addition, the laser can induce special effects. Through femtosecond laser, combined with subsequent etching process planning and design, a variety of special micron 3D structures are obtained on the surface and interior of quartz and glass substrates; at the same time, data analysis and etching simulation are performed through single-beam laser energy distribution theory, predicting the 3D structure that can be obtained by the manufacturing process.%u25a0 Applying microbial fuel cells to the field of wastewater treatment to obtain electrical energy simultaneously is a popular research topic in the environmental field. The electrode fabrication of microbial fuel cells is proposed, and the application of carbon cloth composite electrodes with carbon nanotubes for high-power single-chamber microbial fuel cells is evaluated. Using sewage as the source of bacteria, sodium acetate solution as the fuel, and testing its function, it was found that coating carbon nanotubes on the carbon cloth electrode significantly improved its performance. The maximum output power density was obtained at 64.95 mW/cm2, the COD removal rate was 97%, and the Coulombic efficiency was 67%. Research has proven that electrodes with carbon nanotubes can produce electricity without needing Pt catalysts, showing that carbon cloth composite electrodes with carbon nanotubes have 078 079