Abstract: Among other concepts, this disclosure describes a thermal/optical/electronic authentication system (covert or non-covert) for device/system implementations. The authentication system may be based on different design parameters such as i) materials composition, ii) thickness of material, iii) geometry of material, iv) external effects including use of an external DC bias and curing, etc. The authentication testbeds can be configured to include one or more inks. Using such methods as discussed herein, the authentication can be broadened to include near-IR (700-900 nm), short wave IR (1-2.6 mm), and UVA (300-400 nm) or any spectrum. Printed resistors are very difficult to duplicate without Ag-BST13 ink. If necessary, a printed resistor network on a respective substrate can be hidden using a layer of non-sintered Ag-BST13 (non-conductive).

Abstract: A chip-embedded printed circuit board includes a cavity in a printed circuit board, a chip in the cavity of the printed circuit board, and a thixotropic dielectric filler in a gap in the cavity to seal the chip in the printed circuit board.

Abstract: An ink stabilizing composition includes a polymeric network including an acrylate polymer and a plurality of high aspect ratio particles each having an aspect ratio of about 2:1 to about 30:1 and an average particle diameter of about 0.5 to about 1.2 micrometers.

Abstract: Among other concepts, this disclosure describes a thermal/optical/electronic authentication system (covert or non-covert) for device/system implementations. The authentication system may be based on different design parameters such as i) materials composition, ii) thickness of material, iii) geometry of material, iv) external effects including use of an external DC bias and curing, etc. The authentication testbeds can be configured to include one or more inks. Using such methods as discussed herein, the authentication can be broadened to include near-IR (700-900 nm), short wave IR (1-2.6 mm), and UVA (300-400 nm) or any spectrum. Printed resistors are very difficult to duplicate without Ag-BST13 ink. If necessary, a printed resistor network on a respective substrate can be hidden using a layer of non-sintered Ag-BST13 (non-conductive).

Abstract: A dielectric ink composition includes an epoxy precursor and a photoacid generator. The dielectric ink composition is aerosolable and ultraviolet (UV) curable.

Abstract: A method of fabricating a three-dimensional (3D) object includes atomizing a pre-polymer composition into an aerosol jet stream. The pre-polymer composition includes an epoxy precursor and a photoacid generator. The method further includes depositing the aerosol jet stream onto a substrate to form a first layer of dielectric ink and curing the first layer of dielectric ink using ultraviolet (UV) light. The method further includes depositing the aerosol jet stream onto the first layer of dielectric ink to form a second layer of dielectric ink. The first layer of dielectric ink and the second layer of dielectric ink overlap by at least 50%.

Abstract: This disclosure describes manufacture of a mixture and use of same to fabricate different types of electronic components. In one configuration, the mixture includes: first particles, the first particles being an insulator material; second particles, the second particles being electrically conductive metal material; and a combination of the first particles and the second particles suspended in a printable liquid medium, the printable liquid/solid medium (slurry) being curable into a dielectric layer of material. According to one configuration, the printable material is disposed and cured on a substrate. The first particles and second particles are randomly distributed in the cured printed material (dielectric material). The second particles in the cured dielectric material are transformable into one or more electrically conductive paths, electronic components, etc., via application of heat above a threshold value.

Abstract: A fabrication system is operable to form a structure (such as on a substrate) using a combination of a first (electrically) non-conductive material and a second (electrically) non-conductive. In one embodiment, the structure defined by the first material and the second material defines a void (passageway) in the structure. In one embodiment, exposed surfaces of the first non-conductive material and the second non-conductive material define the void in the structure. Subsequent to creating the structure including the void, the fabrication system fills the void (such as via injection) with an electrically conductive material. After the injected electrically conductive material (such as metal epoxy or other suitable material) solidifies, the fabrication system removes the first non-conductive material (sacrificial material) from the structure. The remaining second material provides structural support for the electrically conductive material.

Abstract: An apparatus includes a heat exchanger configured to transfer heat to a fluid and to absorb heat from the fluid as the fluid flows between a warm end and a cold end of a cryocooler. The heat exchanger includes at least one section having a substrate of at least one allotropic form of carbon and a layer of nanoparticles on or over the substrate. The heat exchanger could include multiple sections, and each section could include one of multiple substrates and one of multiple layers of nanoparticles. The heat exchanger can further include pores through the multiple sections of the heat exchanger, where the pores are configured to allow the fluid to flow through the heat exchanger and to contact the substrates and the layers of nanoparticles. The nanoparticles could include at least one lanthanide element or alloy, and the substrate could include carbon nanotubes or graphene.

Abstract: A position tracking system includes a member extending along a lengthwise axis. Multiple position tracking elements (such as conductive strips) are fabricated to be exposed on a surface of the member. The multiple position tracking elements form a sequence along the lengthwise axis and are spaced apart from each other. The position tracking system further includes a probe. The probe monitors for presences and absence of the position tracking elements disposed in the sequence as the member and corresponding sequence of position tracking elements moves with respect to the probe. Based on the detected presence and absence of position tracking elements, a monitor resource of the position tracking system monitors parameters such as: i) a position of the member along the axis, ii) a rate of movement of the member along the axis over time, iii) a direction of movement of the member along the axis, etc.

Abstract: This disclosure describes manufacture of mixture and use of same to fabricate a respective electronic device. In one embodiment, the mixture includes: perovskite oxide particles and a solvent. The solvent is a water-soluble liquid such as ethylene glycol. A combination of the perovskite oxide particles and the solvent are mixed for subsequent fabrication (such as via a printing head of a printer) of an electronic device.

Abstract: A printed electrical connector design includes two flat patterned thermoplastic plates printed with mechanical registration features that align conductive traces on the two plates of the electrical connector. A top plate is printed with a plurality of raised pedestals and a plurality of metallic traces. A bottom plate is printed with a plurality of recessed channels and a corresponding plurality of metallic traces. The plurality of recessed channels of the bottom plate are configured to mate with the plurality of raised pedestals on the top plate. The pedestals and channels of the top and bottom plates, respectively, serve to align the metallic traces that comprise the electrical connector. The printed electrical connector design allows printed electrical/electronic circuits and/or devices to be manufactured and interfaced with other printed electrical/electronic circuits and/or devices.

Abstract: A fabrication system is operable to form a structure (such as on a substrate) using a combination of a first (electrically) non-conductive material and a second (electrically) non-conductive. In one embodiment, the structure defined by the first material and the second material defines a void (passageway) in the structure. In one embodiment, exposed surfaces of the first non-conductive material and the second non-conductive material define the void in the structure. Subsequent to creating the structure including the void, the fabrication system fills the void (such as via injection) with an electrically conductive material. After the injected electrically conductive material (such as metal epoxy or other suitable material) solidifies, the fabrication system removes the first non-conductive material (sacrificial material) from the structure. The remaining second material provides structural support for the electrically conductive material.

Abstract: A novel ferroelectric ink comprising multiphase Barium Strontium Titanate (BST) in a polymer composite is described. The ink can be employed using direct-ink writing techniques to print high dielectric constant, low loss, and electrostatically-tunable dielectrics on substrates. The substrates can be flexible such as plastics or rigid, such as substrates comprising semiconductor materials or ceramics and the like. The dielectric ink is made by suspending pre-sintered nano/submicron-sized particles of BST in a thermoplastic polymer with a solvent. After printing with the ink, a low temperature curing process is performed at temperatures below 200° C., a temperature too low to sinter BST. Fully printed devices, such as a varactor and a phase shifter using direct ink writing methodologies are described.

Abstract: A printed electrical connector is fabricated via additive manufacturing technology. According to configuration, the printed electrical connector design includes two flat patterned thermoplastic plates printed with mechanical registration features that align conductive traces on the two plates of the electrical connector. A top plate is printed with a plurality of raised pedestals and a plurality of metallic traces. A bottom plate is printed with a plurality of recessed channels and a corresponding plurality of metallic traces. The plurality of recessed channels of the bottom plate are configured to mate with the plurality of raised pedestals on the top plate. The pedestals and channels of the top and bottom plates, respectively, serve to align the metallic traces that comprise the electrical connector. The printed electrical connector design allows printed electrical/electronic circuits and/or devices to be manufactured and interfaced with other printed electrical/electronic circuits and/or devices.

Abstract: An apparatus includes a heat exchanger configured to transfer heat to a fluid and to absorb heat from the fluid as the fluid flows between a warm end and a cold end of a cryocooler. The heat exchanger includes at least one section having a substrate of at least one allotropic form of carbon and a layer of nanoparticles on or over the substrate. The heat exchanger could include multiple sections, and each section could include one of multiple substrates and one of multiple layers of nanoparticles. The heat exchanger can further include pores through the multiple sections of the heat exchanger, where the pores are configured to allow the fluid to flow through the heat exchanger and to contact the substrates and the layers of nanoparticles. The nanoparticles could include at least one lanthanide element or alloy, and the substrate could include carbon nanotubes or graphene.

Abstract: A novel ferroelectric ink comprising multiphase Barium Strontium Titanate (BST) in a polymer composite is described. The ink can be employed using direct-ink writing techniques to print high dielectric constant, low loss, and electrostatically-tunable dielectrics on substrates. The substrates can be flexible such as plastics or rigid, such as substrates comprising semiconductor materials or ceramics and the like. The dielectric ink is made by suspending pre-sintered nano/submicron-sized particles of BST in a thermoplastic polymer with a solvent. After printing with the ink, a low temperature curing process is performed at temperatures below 200° C., a temperature too low to sinter BST. Fully printed devices, such as a varactor and a phase shifter using direct ink writing methodologies are described.

Abstract: A novel ferroelectric ink comprising multiphase Barium Strontium Titanate (BST) in a polymer composite is described. The ink can be employed using direct-ink writing techniques to print high dielectric constant, low loss, and electrostatically-tunable dielectrics on substrates. The substrates can be flexible such as plastics or rigid, such as substrates comprising semiconductor materials or ceramics and the like. The dielectric ink is made by suspending pre-sintered nano/submicron-sized particles of BST in a thermoplastic polymer with a solvent. After printing with the ink, a low temperature curing process is performed at temperatures below 200° C., a temperature too low to sinter BST. Fully printed devices, such as a varactor and a phase shifter using direct ink writing methodologies are described.

Abstract: A novel ferroelectric ink comprising multiphase Barium Strontium Titanate (BST) in a polymer composite is described. The ink can be employed using direct-ink writing techniques to print high dielectric constant, low loss, and electrostatically-tunable dielectrics on substrates. The substrates can be flexible such as plastics or rigid, such as substrates comprising semiconductor materials or ceramics and the like. The dielectric ink is made by suspending pre-sintered nano/submicron-sized particles of BST in a thermoplastic polymer with a solvent. After printing with the ink, a low temperature curing process is performed at temperatures below 200° C., a temperature too low to sinter BST. Fully printed devices, such as a varactor and a phase shifter using direct ink writing methodologies are described.

Abstract: A method is provided for estimating a number of digital subscriber line nodes (220, 230) required to supply, from a line supply source (200), a geographically distributed network of substantially sequentially numbered twisted pair lines with digital subscriber line service. The method comprises the steps of: storing, in number order, data entries for every twisted pair line of the network, each data entry comprising a pair number and a line length of the respective twisted pair line in relation to the line supply source (200); sorting the entries stored in the database by line length; isolating those sorted entries whose twisted pair lines have a line length greater than a predetermined maximum line length in relation to the line supply source (200); sorting the isolated entries by number; and discriminating, from the sorted isolated entries, the presence of discrete groupings of substantially contiguous entries.