TRUSTEES OF PRINCETON UNIVERSITY Patent applications |
Patent application number | Title | Published |
20140334745 | RESOLUTION LIGHT-FIELD IMAGING - A relatively high-resolution image from a conventional camera can be computationally combined with a relatively low-resolution wavefront measurement from, for example, a Shack-Hartmann sensor in order to construct a relatively high-resolution light-field image. | 11-13-2014 |
20130135008 | METHOD AND SYSTEM FOR A RUN-TIME RECONFIGURABLE COMPUTER ARCHITECTURE - A reconfigurable computer architecture is disclosed. The reconfigurable computer architecture has a plurality of logic elements, a plurality of connection switching elements, and a plurality of volatile and/or non-volatile configuration random access memories (RAMs). Each of the configuration RAMs is electrically coupled to at least one of the plurality of logic elements or at least one of the connection switching elements. | 05-30-2013 |
20120217876 | Systems and Methods for Cylindrical Hall Thrusters with Independently Controllable Ionization and Acceleration Stages - Systems and methods may be provided for cylindrical Hall thrusters with independently controllable ionization and acceleration stages. The systems and methods may include a cylindrical channel having a center axial direction, a gas inlet for directing ionizable gas to an ionization section of the cylindrical channel, an ionization device that ionizes at least a portion of the ionizable gas within the ionization section to generate ionized gas, and an acceleration device distinct from the ionization device. The acceleration device may provide an axial electric field for an acceleration section of the cylindrical channel to accelerate the ionized gas through the acceleration section, where the axial electric field has an axial direction in relation to the center axial direction. The ionization section and the acceleration section of the cylindrical channel may be substantially non-overlapping. | 08-30-2012 |
20100124658 | METHOD FOR SYNTHESIZING PHOSPHORESCENT OXIDE NANOPARTICLES - A method for producing activated substantially monodisperse, phosphorescent oxide particles with rare earth element dopants uniformly dispersed therein by mixing a rare earth element dopant precursor powder with an oxide-forming host metal powder to form a solid-phase precursor composition; vaporizing the solid-phase precursor composition; combining the vaporized precursor with an inert carrier gas; contacting the inert carrier gas and the vaporized precursor with a flame fueled by a reactive gas; and uniformly heating the vaporized precursor in the flame to a reaction temperature sufficient to form activated phosphorescent oxide nanoparticles. | 05-20-2010 |
20100056391 | INTEGRATED SCREENING ASSAYS AND METHODS OF USE - A method and system is provided for screening compounds for biological activity in cultures of | 03-04-2010 |
20090297647 | Assays, method and compositions that exploit a mycobacterial iron acquistion pathway in cells - Assays for the identification of antibacterial agents that inhibit mycobacterial growth by interfering with the iron acquisition pathway in host cells are disclosed. Also disclosed are methods of inhibiting mycobacterial growth by interfering with iron uptake or by delivering antibacterial agents to mycobacteria in host cells through the iron uptake pathway, as well as certain compounds that are useful in the assay methods, and also as antibacterial agents. | 12-03-2009 |
20080237181 | HYBRID LAYERS FOR USE IN COATINGS ON ELECTRONIC DEVICES OR OTHER ARTICLES - A method for forming a coating over a surface is disclosed. The method comprises depositing over a surface, a hybrid layer comprising a mixture of a polymeric material and a non-polymeric material. The hybrid layer may have a single phase or comprise multiple phases. The hybrid layer is formed by chemical vapor deposition using a single source of precursor material. The chemical vapor deposition process may be plasma-enhanced and may be performed using a reactant gas. The precursor material may be an organo-silicon compound, such as a siloxane. The hybrid layer may comprise various types of polymeric materials, such as silicone polymers, and various types of non-polymeric materials, such as silicon oxides. By varying the reaction conditions, the wt % ratio of polymeric material to non-polymeric material may be adjusted. The hybrid layer may have various characteristics suitable for use with organic light-emitting devices, such as optical transparency, impermeability, and/or flexibility. | 10-02-2008 |