Stanford researchers have developed a high throughput, low energy consumption, optical method for real-time, image differentiation (image sharpening) using a photonic crystal slab.
Stanford researchers at the Xing Lab have developed a dosimetric features driven- machine learning model for dose volume histograms (DVHs) and dose prediction for volumetric modulated arc therapy (VMAT) planning.
Stanford researchers have proposed two learning techniques for MIMO secondary users (SU) to spatially coexist with Primary Users (PU). Today, most of the spectrum is allocated to primary users for exclusive use.
Stanford researchers have prototyped a medical assistive device which improves efficiency of female self-catheterization by utilizing anatomical landmarks to aid accurate catheter placement in the urethra.
Stanford researchers have developed a new method to more accurately monitor battery State of Charge (SOC) and State of Health (SOH), over its entire lifetime.
Stanford researchers have demonstrated the application of pulsed Focused Ultrasound (pFUS), to non-invasively enhance the function and engraftment of pancreatic islets following transplantation.
The Hong Neurotechnology Lab at Stanford University developed ultrasound-activated nanoscopic light emitters (mechanoluminescent nanoparticles) that are delivered via the blood stream, unlike conventional optogenetics approaches that require invasive fiber optic implants.
A team of Stanford researchers has developed ReMatch, an efficient, data-driven DER (distributed energy resources) planning and decision support framework that accounts for a range of complexities to optimize energy resource planning.
Stanford researchers at the Vuckovic Lab have developed a full chip-scale integration of a Ti:Sapphire laser system which dramatically reduces the size, cost, and power consumption by many orders of magnitude, compared to today's state-of-the-art systems which are bulky and ex
Stanford researchers have developed a low cost, safe, environmentally friendly, rechargeable Zn/MnO2 flow battery with the potential for grid scale energy storage.
Stanford researchers at the Prakash Lab have developed Octopi, a low-cost ($250-$500) and reconfigurable autonomous microscopy platform capable of automated slide scanning and correlated bright-field and fluorescence imaging.
Stanford researchers have optimized air-core coil design for wireless power transfer and demonstrated a 2x improvement over current designs. Existing resonant tank and coils are restraining MHz frequency inductive wireless power transfer efficiency.