|
Princeton Docket # 15-3096-1Researchers at Princeton University, Department of Electrical Engineering, have proposed a method to improve ultrasound image quality. Ultrasound operates like radar, with a probe beam sent to the object and an echo recorded. 2D and 3D images are then built up point-by-point in a scanning fashion. In many cases, however,...
Published: 3/15/2018
|
Inventor(s): Jason Fleischer, JeN-Tang Lu
Keywords(s): Imaging, signal processing
Category(s): Opto-Electronics/ Electrical Engineering, Medical Devices/Diagnostics
|
|
Enhanced 3D Display
Princeton Docket 13-2935-1
Researchers at Princeton University have developed a novel device that enhances the angular resolution available for 3D displays. Enhanced layered 3D is a low-cost method for increasing the fidelity of glasses-free 3D displays. This method allows for more variation of images to be experienced by multiple...
Published: 3/15/2018
|
Inventor(s): Jason Fleischer, Stefan Muenzel
Keywords(s): computers/software, Imaging, microscopy, Opto-Electronics/ELE ENG
Category(s): Computers and Software, Opto-Electronics/ Electrical Engineering
|
|
Improved-Resolution Light-Field Imaging
Princeton Docket # 13-2912-1
The Princeton researchers have developed a new method to improve the currently available light-field imaging. A novel feature is that this method can go beyond the resolution limit of current light-field imagers.
The resolution of the current light-field imaging system, both lateral...
Published: 3/15/2018
|
Inventor(s): Jason Fleischer, ChieN-Hung Lu, Stefan Muenzel
Keywords(s): computers/software, Imaging, microscopy, Opto-Electronics/ELE ENG, process optimization
Category(s): Computers and Software, Opto-Electronics/ Electrical Engineering
|
|
Princeton Docket # 12-2798
Tomography
is a method for three-dimensional imaging by sectioning, through the use of
penetrating waves. Modern variations of
tomography involve gathering projection data from multiple directions and using
a computer to numerically reconstruct the final image. Tomography has been widely applied for
medical imaging,...
Published: 3/15/2018
|
Inventor(s): Jason Fleischer, Nicolas Pegard
Keywords(s): Imaging, medical device, Opto-Electronics/ELE ENG
Category(s): Opto-Electronics/ Electrical Engineering
|
|
Princeton Dockets # 12-2746, 12-2747, & 12-2748
Researchers at Princeton University have developed novel
modifications to microfluidic microscope (MFM) devices. These new features will allow full
three-dimensional (3D) profiling of objects, while retaining the simplicity and
high throughput of traditional MFMs.
Microfluidic Microscopy is...
Published: 3/15/2018
|
Inventor(s): Jason Fleischer, Nicolas Pegard
Keywords(s): life science research tools, medical device, Opto-Electronics/ELE ENG
Category(s): Opto-Electronics/ Electrical Engineering, Medical Devices/Diagnostics
|
|
Princeton Docket # 11-2701
Optical manipulation of light has become an increasingly popular strategy to enhance light harvesting efficiencies in opto-electronic devices. Despite recent advances in nano-scale patterning techniques that have enabled the creation of discrete metallic building blocks or continuous metallic films having nano-hole arrays,...
Published: 3/15/2018
|
Inventor(s): YueH-Lin Loo, Jongbok Kim, Pilnam Kim, Howard Stone, Nicolas Pegard, Jason Fleischer
Keywords(s): Opto-Electronics/ELE ENG, solar cell
Category(s): Opto-Electronics/ Electrical Engineering, Ceramics/Material Sciences
|
|
Princeton Docket #08-2453
Researchers at Princeton University have developed a new process of filtering and enhancing signals from a noisy background, based on the non-linear interaction between coherent and incoherent waves. Princeton is currently seeking industrial collaborators to commercialize this technology.
The new process is an...
Published: 3/15/2018
|
Inventor(s): Jason Fleischer, Dmitry Dylov
Keywords(s): data security, signal processing, steganography
Category(s): Opto-Electronics/ Electrical Engineering
|