Abstract: A field effect transistor having a channel that comprises three-dimensional graphene foam. The subject matter of the invention concerns a three dimensional field-effect transistor having a channel based on graphene foam and the use of ionic liquid as a gate. The graphene foam is made of a three-dimensional network of single and double layer graphene that extends in all the three dimensions. Metal contacts on either end of the graphene foam form the drain and source contacts of the transistor.

Abstract: A microplasma generator includes first and second conductive resonators disposed on a first surface of a dielectric substrate. The first and second conductive resonators are arranged in line with one another with a gap defined between a first end of each resonator. A ground plane is disposed on a second surface of the dielectric substrate and a second end of each of the first and second resonators is coupled to the ground plane. A power input connector is coupled to the first resonator at a first predetermined distance from the second end chosen as a function of the impedance of the first conductive resonator. A microplasma generating array includes a number of resonators in a dielectric material substrate with one end of each resonator coupled to ground. A micro-plasma is generated at the non-grounded end of each resonator. The substrate includes a ground electrode and the microplasmas are generated between the non-grounded end of the resonator and the ground electrode.

Abstract: An apparatus for controlling propagation of an electromagnetic wave includes a metamaterial having an array of cells, each cell containing a metallic structure having a resonant frequency; a plurality of devices integrated in the metamaterial, each of said devices being in electrical communication with a metallic structure in a cell in the array of cells; and a controller for electrically activating each of said plurality of devices to cause said resonant frequency to change, thereby causing at least one of a permeability and permittivity of the metamaterial to change.

Abstract: Among other things, devices for use in fluorescence or luminescence lifetime imaging are described. The devices include integrated complementary metal-oxide semiconductor (CMOS) chips that include an imaging region and a time-to-digital converter. The imaging region includes a photodetector for receiving optical signals. The time-to-digital converter provides digital phase output based on the received optical signals.

Abstract: A method of making an electrically active structure includes applying a backplane onto a substrate, applying a paint layer onto said backplane, applying a stencil layer on said paint layer, patterning an electrically active structure onto said paint layer through said stencil layer, and removing said stencil layer.

Abstract: A manufacture for supporting propagation of terahertz waves includes a stack of layers made of a conformal protective polymer coating material; and an array of cells patterned on each of said layers, each cell including a metallic structure.

Abstract: A microplasma generator includes first and second conductive resonators disposed on a first surface of a dielectric substrate. The first and second conductive resonators are arranged in line with one another with a gap defined between a first end of each resonator. A ground plane is disposed on a second surface of the dielectric substrate and a second end of each of the first and second resonators is coupled to the ground plane. A power input connector is coupled to the first resonator at a first predetermined distance from the second end chosen as a function of the impedance of the first conductive resonator. A microplasma generating array includes a number of resonators in a dielectric material substrate with one end of each resonator coupled to ground. A micro-plasma is generated at the non-grounded end of each resonator. The substrate includes a ground electrode and the microplasmas are generated between the non-grounded end of the resonator and the ground electrode.

Abstract: An apparatus for controlling propagation of an electromagnetic wave includes a metamaterial having an array of cells, each cell containing a metallic structure having a resonant frequency; a plurality of devices integrated in the metamaterial, each of said devices being in electrical communication with a metallic structure in a cell in the array of cells; and a controller for electrically activating each of said plurality of devices to cause said resonant frequency to change, thereby causing at least one of a permeability and permittivity of the metamaterial to change.

Abstract: A low power BPSK demodulator having a simple architecture, compact design and reliable is provided. The BPSK demodulator includes a first branch (210) having a first mixer (212) and a first low pass filter (214), a second branch (220) coupled to the first branch at the output of the first low pass filter (214) and input of the first mixer (212) and having a second mixer (222), and a third branch (230) coupled to the second branch at the input and output of the second mixer (222) and having a third mixer (232) a second low pass filter (234) and a voltage control oscillator (236), wherein the third branch and the second branch form a charge pumped based phase lock loop that locks onto a carrier frequency of the BPSK demodulator.

Abstract: An integrated imaging system, e.g., a microsystem, for detecting activity of a biological target, for example, in response to a stimulus, includes an array of pixels arranged on a substrate, each pixel including a photodetector disposed to be in optical communication with a biological target on a surface of the substrate; and at least first and second electrodes arranged in electrical communication with the biological target.

Abstract: A low power BPSK demodulator having a simple architecture, compact design and reliable is provided. The BPSK demodulator includes a first branch (210) having a first mixer (212) and a first low pass filter (214), a second branch (220) coupled to the first branch at the output of the first low pass filter (214) and input of the first mixer (212) and having a second mixer (222), and a third branch (230) coupled to the second branch at the input and output of the second mixer (222) and having a third mixer (232) a second low pass filter (234) and a voltage control oscillator (236), wherein the third branch and the second branch form a charge pumped based phase lock loop that locks onto a carrier frequency of the BPSK demodulator.

Abstract: Systems and methods are provided for performing a background calibration technique on one or more stages of a pipeline Analog-to-Digital Converter (ADC). The systems and methods employs a slow but accurate analog-to-digital converter or a slow but accurate ideal pipeline stage to correct for the residue errors in a non-ideal pipeline stage using an error function and a correction algorithm. The correction algorithm determines optimal parameters of the error function, so that the error function can be utilized to compensate for errors in the ADC. The correction algorithm and results can be applied in the digital domain or in the analog domain.

Abstract: Systems and methods are provided for performing a background calibration technique on one or more stages of a pipeline Analog-to-Digital Converter (ADC). The systems and methods employs a slow but accurate analog-to-digital converter or a slow but accurate ideal pipeline stage to correct for the residue errors in a non-ideal pipeline stage using an error function and a correction algorithm. The correction algorithm determines optimal parameters of the error function, so that the error function can be utilized to compensate for errors in the ADC. The correction algorithm and results can be applied in the digital domain or in the analog domain.