Researchers in Prof. Simone D'Amico's Space Rendezvous Laboratory have developed a high fidelity, high dynamic range testbed to stimulate a broad range of cameras and verify functionality and performance for the next generation of vision-based satellite navigation systems.
Stanford researchers in the Tass Lab have patented a device and algorithm designed to optimize Acoustic Coordinated Reset (CR) stimuli for individualized tinnitus treatment.
Stanford researchers developed a wireless power transfer mechanism that will charge devices while on the move, or in use. The mechanism uses a parity-time symmetric circuit incorporating a nonlinear gain saturation element.
Stanford researchers have developed methods of extracting photon depth of interaction (DOI) information to develop less complex, cost effective DOI detector technologies for high resolution positron emission tomography (PET).
Stanford researchers have invented a decoder for multiplexed readouts of imaging arrays that optimizes the signal-to-noise ratio (SNR) of the decoded detector pixel signals.
Stanford researchers have developed a patented method for precisely controlling the force exerted by a permanent magnet for use in medical systems. This system is ideally suited for applications such as robotic catheter placement and endoscopy capsule manipulation.
Researchers in Prof. Julia Salzman's laboratory have developed a sensitive, specific algorithm for automated, high-throughput detection of RNA fusions from RNA-Seq data.
Researchers in Dr. Alfred Spormann's lab have developed a method of using co-cultures to enhance microbial electrosynthesis to allow more efficient production of desired products such as biofuel.
Professor Marc Levoy and collaborators have enhanced the performance of the light field microscope (LFM) by solving the problem of non-uniform spatial resolution across the working range, especially the low spatial resolution at the native objective plane (in the middle of the
Engineers in Prof. H.-S. Philip Wong's laboratory have developed a lower power, three-dimensional resistive random access memory (RRAM) device using an atomically thin graphene edge electrode.
Researchers at Stanford have developed methods for preparing photo-, and chemical-, cross-linkable three-dimensional matrices for the controlled delivery of bioactive molecules for therapeutic applications.
Electronic devices made from single crystal thin films attached to inexpensive support substrates offer reduced material costs compared to wafer-based devices; however, scalable and inexpensive processes for producing these single crystal film structures have remained elusive.
Solar cells containing halide perovskite absorbers have shown large improvements in power conversion efficiency over the last eight years and now exceed 20%. This makes them competitive with many commercial technologies like polycrystalline silicon and CdTe.