Researchers from Stanford University and the Max Planck Institute have patented a new marker-less approach to capturing human performances from multi-view video.
Researchers at Stanford University have over come some of the critical challenges for wireless broadband users to remain connected in highly mobile environments.
Stanford researchers have patented a method for detecting malicious bots, programs that are installed as viruses on a computer and then proceed to execute malicious commands from another remote computer.
Dr. Richard Zare and colleagues have developed an inexpensive, fast and simple method for treating polyethylene terephthalate (PET) blood collection tubes (BCTs) to remove bias and interference in various blood analysis procedures.
Researchers in Dr. Juan Rivas-Davila's lab have developed 3D printing methods to make aircore inductors and capacitors with more complex geometries and functionality than components using printed circuit boards.
Voice to Text and Sketch (V2TS) is a patented software program which allows text or drawings to be synchronized to recorded audio. Each portion of text or section of a drawing is associated with an audio segment recorded at the time it was written/sketched.
This patented technology is a magnetically actuated photonic crystal sensor system. It utilizes a photonic crystal (PC) coupled to magnetic material which is then mounted on an optical fiber.
Stanford researchers have invented a system for identifying head impacts and rejecting spurious motion events. The system has been implemented in an instrumented mouthguard which measures head kinematics on the sports field.
Precision in surgical removal of cancer is guided by pathological assessment of resected tissues, and there is a dire need to reduce the time and distance between the critical diagnostic events and the surgical procedure.
Researchers in Dr. Michael Lin's lab have developed a fluorescent voltage sensor for non-invasive optical monitoring of electrical events in living cells in vitro and in vivo.
Hydrogel-based tissue engineering scaffolds are widely used for culturing cells in three dimensions (3D) due to their tissue-like water content, tunable biochemical and physical properties, and ease of cell encapsulation and distribution in 3D.
Rechargeable lithium sulfur batteries have attracted great interest in recent years because of their high theoretical specific energy, which is several times that of current lithium-ion batteries.