I describe results from my research on optical MEMS at Berkeley Sensor & Actuator Center. High precision microlenses (200~1000μm diameters), fabricated utilizing hydrophobic effects and polymer-printing technology, have 343~7862μm focal lengths and show λ/5~λ/80 wavefront aberrations at 635nm. Batch-processed polarization-beam splitters, made from low-stress Si3N4, produced extinction ratios of 16dB and 21dB at λ=635nm for transmitted and reflected light, respectively. Micromachined frequency-addressed microlens array can expand the dynamic range of a Shack-Hartmann (S-H) wavefront sensor beyond 144mrad, an improvement at least by a factor of 10 over conventional systems. High performance torsional microscanners, produced using our CMOS-compatible high-yield process, demonstrated a high-precision 2-D scan (scanning precision: <1μm on the scan plane). A fast, MEMS-based, phaseshifting interferometer with accuracy of 5.5nm, could continuously measure at rates up to 23Hz, a factor-of-23 improvement over PZT-based phase-shifting interferometers. I hope to leave you convinced, as am I, that opportunities for fruitful applications are extremely widespread in optical MEMS.