Abstract: Predictive control techniques for an electrified powertrain of a hybrid electric vehicle (HEV) include maintaining a database of past measured operational parameters of an electrified powertrain during a plurality of past drive cycles of the HEV, monitoring and comparing measured operational parameters of the electrified powertrain during a current drive cycle of the HEV to the past measured operational parameters of the electrified powertrain stored in the database, predicting or estimating operational parameters of the electrified powertrain for a remainder of the current drive cycle of the HEV based on the comparison, and controlling the electrified powertrain during the remainder of the current drive cycle of the HEV based on the predicted/estimated operational parameters of the electrified powertrain including at least controlling recharging of a high voltage (HV) battery system to increase a fuel economy or operational efficiency of the electrified powertrain.

Abstract: A fire suppression nozzle includes an outer tubular member, an inner tubular member co-cylindrical with the outer tubular member and extending through the outer tubular member, wherein the inner tubular member comprises a first chamber, and the outer tubular member and the inner tubular member cooperatively define a second chamber, multiple disc members extending radially outward relative to an outer surface of the outer tubular member, a first and second set of openings extending through the inner tubular member to fluidly couple the first chamber with the second chamber, and a first and second set of discharge openings extending through the outer tubular member to fluidly couple the second chamber with an external environment, wherein the first and second set of openings are longitudinally aligned with the first and second set of discharge openings.

Abstract: A method of making a fiber reinforced energetic composite is provided. The method includes providing a mold or mandrel defining a shape for the fiber reinforced energetic composite, providing an impregnated fiber layup over the mold or mandrel, and curing the impregnated fiber layup. The impregnated fiber layup includes a fiber layup and polymer resin, the fiber layup formed from a plurality of reinforcing fiber layers and an energetic polymer nanocomposite disposed adjacent one or more of the reinforcing fiber layers with the polymer resin impregnated within the reinforcing fiber layers. The energetic polymer nanocomposite includes core-shell nanoparticles entrained in a thermoplastic polymer matrix where the core-shell nanoparticles include a core made of metal and at least one shell layer made of metal oxide disposed on the core or a core made of metal oxide and at least one shell layer made of metal disposed on the core.

Abstract: Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor and a detector. The at least one tamper-respondent sensor includes conductive lines which form, at least in part, at least one tamper-detect network of the tamper-respondent sensor(s). In addition, the tamper-respondent sensor(s) includes at least one interconnect element associated with one or more conductive lines of the conductive lines forming, at least in part, the tamper-detect network(s). The interconnect element(s) includes at least one interconnect characteristic selected to facilitate obscuring a circuit lay of the at least one tamper-detect network. The at least one interconnect element is undetectable by x-ray, and the conductive lines are detectable by x-ray. In operation, the detector monitors the tamper-detect network(s) of the tamper-respondent sensor(s) for a tamper event.

Abstract: Tamper-respondent assemblies and fabrication methods are provided which utilize liquid crystal polymer layers in solid form. The tamper-respondent assemblies include a circuit board, and an enclosure assembly mounted to the circuit board to enclose one or more electronic components coupled to the circuit board within a secure volume. The assembly includes a tamper-respondent sensor that is a three-dimensional multilayer sensor structure, which includes multiple liquid crystal polymer layers, and at least one tamper-detect circuit. The at least one tamper-detect circuit includes one or more circuit lines in a tamper-detect pattern disposed on at least one liquid crystal polymer layer of the multiple liquid crystal polymer layers. Further, a monitor circuit is provided disposed within the secure volume to monitor the at least one tamper-detect circuit of the tamper-respondent sensor for a tamper event.

Abstract: Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

Abstract: Tamper-respondent assemblies are provided which include an enclosure with an edge surface, and a tamper-respondent sensor. The tamper-respondent sensor covers, at least in part, the edge surface and an inner surface of the enclosure. The sensor includes at least one tamper-detect circuit. The tamper-detect circuit(s) includes a conductive trace(s) in a tamper-detect pattern. The tamper-respondent sensor includes exposed regions and unexposed regions of the conductive trace(s) at the edge surface of the enclosure to facilitate an adhesive directly contacting the at least one conductive trace in the exposed regions.

Abstract: A fiber reinforced energetic composite is provided. The fiber reinforced energetic composite includes reinforcing fiber embedded in a cured polymer matrix and energetic polymer nanocomposite disposed in the reinforcing fiber. The energetic polymer nanocomposite including core-shell nanoparticles entrained in a polymer matrix. The core-shell nanoparticles include a core made of a metal and at least one shell layer made of a metal oxide disposed on the core or a core made a metal oxide and at least one shell layer made of a metal disposed on the core. The method of making a fiber reinforced energetic composite is also provided. Further, a composite container made of fiber reinforced energetic composite is further provided.

Abstract: Methods of fabricating tamper-respondent assemblies with bond protection are provided which include at least one tamper-respondent sensor having unexposed circuit lines forming, at least in part, one or more tamper-detect network(s), and the tamper-respondent sensor having at least one external bond region. The tamper-respondent assembly further includes at least one conductive trace and an adhesive. The conductive trace(s) forms, at least in part, the one or more tamper-detect network(s), and is exposed, at least in part, on the tamper-respondent sensor(s) within the external bond region(s). The adhesive contacts the conductive trace(s) within the external bond region(s) of the tamper-respondent sensor(s), and the adhesive, in part, facilitates securing the at least one tamper-respondent sensor within the tamper-respondent assembly.

Abstract: Tamper-respondent assemblies are provided which include an enclosure assembly mounted to a circuit board and enclosing an electronic component(s) within a secure volume. The enclosure assembly includes an enclosure with an edge surface coupled to the circuit board, and a tamper-respondent sensor. The tamper-respondent sensor covers the edge surface and an inner surface of the enclosure. The sensor includes multiple layers, and at least one tamper-detect circuit. The tamper-detect circuit(s) includes a conductive trace(s) in a tamper-detect pattern covered, at least in part, by at least one layer of the multiple layers. The at least one layer is partially removed to provide exposed regions and unexposed regions of the conductive trace(s) at the edge surface of the enclosure. The conductive trace(s) is contacted where exposed by an adhesive securing the sensor to the circuit board. A monitor circuit monitors the tamper-detect circuit(s) for a tamper event.

Abstract: Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor and a detector. The at least one tamper-respondent sensor includes conductive lines which form, at least in part, at least one tamper-detect network of the tamper-respondent sensor(s). In addition, the tamper-respondent sensor(s) includes at least one interconnect element associated with one or more conductive lines of the conductive lines forming, at least in part, the tamper-detect network(s). The interconnect element(s) includes at least one interconnect characteristic selected to facilitate obscuring a circuit lay of the at least one tamper-detect network. In operation, the detector monitors the tamper-detect network(s) of the tamper-respondent sensor(s) for a tamper event.

Abstract: Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor and a detector. The at least one tamper-respondent sensor includes conductive lines which form, at least in part, at least one tamper-detect network of the tamper-respondent sensor(s). In addition, the tamper-respondent sensor(s) includes at least one interconnect element associated with one or more conductive lines of the conductive lines forming, at least in part, the tamper-detect network(s). The interconnect element(s) includes at least one interconnect characteristic selected to facilitate obscuring a circuit lay of the at least one tamper-detect network. In operation, the detector monitors the tamper-detect network(s) of the tamper-respondent sensor(s) for a tamper event.

Abstract: Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor and a detector. The at least one tamper-respondent sensor includes conductive lines which form, at least in part, at least one tamper-detect network of the tamper-respondent sensor(s). In addition, the tamper-respondent sensor(s) includes at least one interconnect element associated with one or more conductive lines of the conductive lines forming, at least in part, the tamper-detect network(s). The interconnect element(s) includes at least one interconnect characteristic selected to facilitate obscuring a circuit lay of the at least one tamper-detect network. The at least one interconnect element is undetectable by x-ray, and the conductive lines are detectable by x-ray. In operation, the detector monitors the tamper-detect network(s) of the tamper-respondent sensor(s) for a tamper event.

Abstract: Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

Abstract: Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

Abstract: Tamper-respondent assemblies and fabrication methods are provided which utilize liquid crystal polymer layers in solid form. The tamper-respondent assemblies include a circuit board, and an enclosure assembly mounted to the circuit board to enclose one or more electronic components coupled to the circuit board within a secure volume. The assembly includes a tamper-respondent sensor that is a three-dimensional multilayer sensor structure, which includes multiple liquid crystal polymer layers, and at least one tamper-detect circuit. The at least one tamper-detect circuit includes one or more circuit lines in a tamper-detect pattern disposed on at least one liquid crystal polymer layer of the multiple liquid crystal polymer layers. Further, a monitor circuit is provided disposed within the secure volume to monitor the at least one tamper-detect circuit of the tamper-respondent sensor for a tamper event.

Abstract: Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

Abstract: Tamper-respondent assemblies and methods of fabrication are provided which include an enclosure, an in-situ-formed tamper-detect sensor, and one or more flexible tamper-detect sensors. The enclosure encloses, at least in part, one or more electronic components to be protected, and the in-situ-formed tamper-detect sensor is formed in place over an inner surface of the enclosure. The flexible tamper-detect sensor(s) is disposed over the in-situ-formed tamper-detect sensor, such that the in-situ-formed tamper-detect sensor is between the inner surface of the enclosure and the flexible tamper-detect sensor(s). Together the in-situ-formed tamper-detect sensor and flexible tamper-detect sensor(s) facilitate defining, at least in part, a secure volume about the one or more electronic components.

Abstract: Assembly apparatuses and processes are provided which include a pressure cure fixture. The pressure cure fixture is sized to reside within a container, such as an electronic enclosure, and facilitate applying pressure to an adhesive disposed over an inner surface of the container. The pressure cure fixture is formed of a material with a higher coefficient of thermal expansion (CTE) than the container, and is sized to correspond, at least in part, to an inner space of the container while allowing for the adhesive and a surface-mount element to be disposed between the pressure cure fixture and the inner surface of the container. When heated, the pressure cure fixture expands greater than the container and imparts the pressure to the surface-mount element and the adhesive to facilitate securing the surface-mount element to the inner surface of the container.

Abstract: Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).