Abstract: Improved temperature independence in infrared light emitting diodes (IRLEDs). The active stage groups (ASGs) occur at or at an integer multiple of each antinode of the e-field of the desired center wavelength. The structure is designed to yield increased efficiency at low (cryogenic) temperatures with a wide range of operational temperature independence. The structure may be designed to provide a wide range of temperature independent operation near room temperature. The spacing (S) between the centers of the active stage groups may be varied to create a more broad and shallow peak of the temperature dependence of the antinode enhancement. The IRLED may be an interband cascade LED.

Abstract: In an infrared (IR) scene projector device or thermal emission array comprising a plurality of vertically aligned carbon nanotubes disposed proximate to a thermally conductive substrate, the plurality of carbon nanotubes (CNTs) may be (i) arranged as in FIGS. 2 and 4B as a sparsely populated forest, with large gaps between the CNTs; or (ii) arranged as in FIGS. 3 and 4C as patches (clusters) of CNTs separated by gaps; or (iii) arranged as a combination of clusters separated by gaps wherein each cluster comprises a sparsely populated forest of CNTs.

Abstract: A system and method for a resistor for detecting the relative level of moisture content in a humid environment. The resistor has a first layer of conductive material on a top surface of a substrate having a bend. The conductive material is exposed to atmospheric conditions. The first layer of conductive material has a static condition moisture content and a measurable electrical resistance that changes predictably when the amount of moisture content in contact with the first layer of conductive material changes from the static condition. The change of resistance of the first layer of conductive material corresponds to a change in the moisture content in contact with the first layer of electrically conductive material.

Abstract: A system and method for a bi-directional deflectable resistor. The bi-directional deflectable resistor has a first layer of conductive material on a top surface of a substrate and a second layer of conductive material on a bottom surface of a substrate, each layer having a resistance that changes predictably when an electrical signal is applied thereto. The change of resistance of either the first layer of conductive material or the second layer of conductive material reflects an amount of deflection of the respective layer. Having two layers of conductive material allows for the measurement of deflection in all directions.

Abstract: A system and method for a deflectable resistor. The deflectable resistor has a first layer of conductive material and a second layer of conductive material on a top surface of a substrate, said first layer of conductive material having a resistance that changes predictably. The change of resistance of the first layer of conductive material reflects an amount of deflection of the respective layer. A dielectric is placed over the first and second layers of conductive material. A third layer of conductive material is placed thereon. The dielectric material electrically insulates the first and second layers from the third layer.