Abstract: Building a complete ship hull, including many internals (bulkhead, holds), as a single, 3D printed device. A Stewart crane is used for gross positioning, while a multitude of beam deposition arms can be used for finer positioning. In a shipbuilding method, this means that the hull, floors, main piping, tanks, quarters, stairs, doorways, etc. can all be printed, in place, as part of a multi-step process.

Abstract: Structured light approaches utilize a laser to project features, which are then captured with a camera. By knowing the disparity between the laser emitter and the camera, the system can triangulate to find the range. Four, 185 degree field-of-view cameras provide overlapping views over nearly the whole unit sphere. The cameras are separated from each other to provide parallax. A near-infrared laser projection unit sends light out into the environment, which is reflected and viewed by the cameras. The laser projection system will create vertical lines, while the cameras will be displaced from each other horizontally. This relative shift of the lines, as viewed by different cameras, enables the lines to be triangulated in 3D space. At each point in time, a vertical stripe of the world will be triangulated. Over time, the laser line will be rotated over all yaw angles to provide full a 360 degree range.

Abstract: The Canine Handler Operations Positioning System (the Inventors) taught by the present invention consists of one or more dog-worn sensor, one or more handler's shoe-worn sensor, and algorithms for maintaining localization of units of canines and handlers traveling in GPS and GPS-denied areas. The present invention adapts the localization algorithms from the human-based system to dogs, increase performance, reduce SWAP, and further refine the system based on user feedback. The human worn system is modified for the human handler for maximum operational practicality in regard to batteries, size, and interoperability to a radio. The Canine Handler Operations Positioning System (the Inventors) focuses on developing the dog-worn positioning system, modifying the handler's positioning sensor if needed, and integrating the system with an OCU. The complete the Inventors system would provide a positioning solution for both the dog(s) and handler(s).

Abstract: An apparatus and method for multi-stage printing teaches means for removing and replacing a printed component during the printing process and accurately placing the component in the printer for continuation of the printing process. This can be accomplished through the use of a scanner, probe machine, or scanning Additionally, the present invention teaches the use of heating means in combination with a 3D printer to overcome additional issues with multi-sage printing.

Abstract: A compiler transforms the source code into object code, but it will postpone the assignment of all of the machine language jumps until installed time. This can be performed by labeling the jumps during compiled time, similarly to how variables are labeled for later indexing by the debugger. At installation time, given a random key, the installer will take the jump labels and assign random ordering of the code and data using the key as a seed. The final effect is that the same source code can potentially generate an infinite number of object codes, with the exact same functionality of execution. The main difference, however, is that as more jump labels are included, less fixed offsets between buffers are available to the black hat.

Abstract: The present invention is a method and system for using a 3D printer for printing various tunable antennas. In one embodiment, and exponent antenna is created by printing a board using a 3D printer in combination with vacuum metallization to create the antenna and provide engineered break points for adjusting the printed antenna for the most effective gain. In another embodiment, a spiral cavity backed antenna is printed using a combination of a 3D printer and vacuum metallization. In a third embodiment, a horn antenna is printed using a combination of a 3D printer engineered break points for adjustment and a hinged version with an actuator creating a new antenna.

Abstract: The Canine Handler Operations Positioning System (the Inventors) taught by the present invention consists of one or more dog-worn sensor, one or more handler's shoe-worn sensor, and algorithms for maintaining localization of units of canines and handlers traveling in GPS and GPS-denied areas. The present invention adapts the localization algorithms from the human-based system to dogs, increase performance, reduce SWAP, and further refine the system based on user feedback. The human worn system is modified for the human handler for maximum operational practicality in regard to batteries, size, and interoperability to a radio. The Canine Handler Operations Positioning System (the Inventors) focuses on developing the dog-worn positioning system, modifying the handler's positioning sensor if needed, and integrating the system with an OCU. The complete the Inventors system would provide a positioning solution for both the dog(s) and handler(s).

Abstract: The proposed system, Delayed Telop Aid (DTA), improves the teleoperator's ability to control the vehicle in a three step process. First, DTA predicts robot motion given the operators commands. Second, DTA creates synthetic images to produce a video feed that looks as if the robot communication link had no delay and no reduced bandwidth. Finally, DTA performs closed loop control on the robot platform to ensure that the robot follows the operator's commands. A closed loop control of the platform makes sure that the predicted pose after the delay (and therefore the image presented to the operator) is achieved by the platform. This abstracts away the latency-sensitive parts of the robot control, making the robot's behavior stable in the presence of poorly characterized latency between the operator and the vehicle.

Abstract: An atomic clock is used in conjunction with the GNSS receiver and the inertial sensors, creating a more capable inertial navigation system (INS). The system is composed of a GNSS receiver, an accurate clock, and a mechanism for measuring relative pose changes. The system being presented utilizes an inertial measurement unit (IMU) to provide the relative pose changes, but other mechanisms can be used—like visual and ladar odometry. The GNSS receiver measures the pseudo-ranges to the GNSS satellites in the field of view. These measurements are “time tagged” with the accuracy of the atomic clock. The relative motion between the pseudo-ranges is measured using the IMU. Finally, the lock is achieved by filtering these measurements. The filtering mechanism can vary, from the traditional Kalman Filters to other mechanisms that attempt to minimize the mean square error.

Abstract: The proposed method outlines a new control mechanism well-suited for small, unmanned aerial vehicles traversing in a GPS-denied areas. It has the strong advantage of simplifying the interface, so that even an untrained operator can handle the difficult, dynamic problems encountered in closed quarters. The proposed system seamlessly integrates point-and-click control with way-point navigation, in an intuitive interface. An additional advantage of the proposed system is that it adds minimal hardware to the payload of the UAV, and can possibly, strongly diminish the bandwidth and delay effects of the communication channel.

Abstract: The Canine Handler Operations Positioning System (the Inventors) taught by the present invention consists of one or more dog-worn sensor, one or more handler's shoe-worn sensor, and algorithms for maintaining localization of units of canines and handlers traveling in GPS and GPS-denied areas. The present invention adapts the localization algorithms from the human-based system to dogs, increase performance, reduce SWAP, and further refine the system based on user feedback. The human worn system is modified for the human handler for maximum operational practicality in regard to batteries, size, and interoperability to a radio. The Canine Handler Operations Positioning System (the Inventors) focuses on developing the dog-worn positioning system, modifying the handler's positioning sensor if needed, and integrating the system with an OCU. The complete the Inventors system would provide a positioning solution for both the dog(s) and handler(s).

Abstract: A system for localizing a swarm of robotic platforms utilizing ranging sensors. The swarm is localized by purposely leaving some of the platforms of the swarm stationary, providing localization to the moving ones. The platforms in the swarm can alternate between a stationary and moving state.

Abstract: UMAPS is a multifaceted system that can be robot-mounted, human-worn, or canine carried. UMAPS produces real-time, 3D mapping and localization for the user as they move throughout a GPS-denied environment (e.g. buildings, caves, or tunnels). An Operator Control Unit (OCU) displays information collected by UMAPS; 2D floorplans; 3D textured-enriched surfaces of the structure's interior; and the location of the users within that structure. UMAPS has an open architecture that allows it to function with any OCU.

Abstract: The system described assumes that the physical properties of the bind sites will be sufficiently repeatable to be tabulated based on a limited set of control constraints: filament material, temperature of the print head, feed rate, temperature of the substrate, and filament orientations at the bind site, etc. The main idea of this system is to utilize the bind sites and the connection and directionality of the threads as a lattice that can then be fed into a finite element analysis (FEA) algorithm for simulation in order to extract the macro physical properties of the part being produced. These repeatable bind site tabulated values can then be used to provide the cell properties for the FEA. The micro properties of the bind site can also be encoded into explicit equations, neural networks or other approximators.

Abstract: UMAPS is a multifaceted system that can be robot-mounted, human-worn, or canine carried. UMAPS produces real-time, 3D mapping and localization for the user as they move throughout a GPS-denied environment (e.g. buildings, caves, or tunnels). An Operator Control Unit (OCU) displays information collected by UMAPS; 2D floorplans; 3D textured-enriched surfaces of the structure's interior; and the location of the users within that structure. UMAPS has an open architecture that allows it to function with any OCU. UMAPS has three distinct subsystems: obstacle maps for robot mobility, mapping, and positioning.

Abstract: UMAPS is a multifaceted system that can be robot-mounted, human-worn, or canine carried. UMAPS produces real-time, 3D mapping and localization for the user as they move throughout a GPS-denied environment (e.g. buildings, caves, or tunnels). An Operator Control Unit (OCU) displays information collected by UMAPS; 2D floorplans; 3D textured-enriched surfaces of the structure's interior; and the location of the users within that structure. UMAPS has an open architecture that allows it to function with any OCU.

Abstract: The present invention is a method and system for using a 3D printer for printing various tunable antennas. In one embodiment, and exponent antenna is created by printing a board using a 3D printer in combination with vacuum metallization to create the antenna and provide engineered break points for adjusting the printed antenna for the most effective gain. In another embodiment, a spiral cavity backed antenna is printed using a combination of a 3D printer and vacuum metallization. In a third embodiment, a horn antenna is printed using a combination of a 3D printer engineered break points for adjustment and a hinged version with an actuator creating a new antenna.

Abstract: An apparatus and method for multi-stage printing teaches a 3D printer in combination with one or more additional dispensing nozzles. One or more additional dispensing nozzles are combined with the 3D for filling cavities with other compounds such as foam, sterilizing parts by spraying printed mold with disinfectant or antibacterial treatments, and embedding parts or other materials such as paper, fiberglass, or carbon fiber within the printing layers for additional strength and changing mold properties of a final product. In other embodiments, the apparatus of the present invention can be used in combination with a robotic packaging mechanism for bagging sterilized parts for shipment.

Abstract: A printing station teaching a control chamber for printing that is either part of the 3D printer or in which the 3D printer is enclosed. Additionally, the printing station must be equipped with assembly directions for building various devices from two or more printed component parts, an inventory of non-printable parts, a robot or other automated means for selecting and combining component parts into devices, as well as downloadable software and encryption for securing the devices and limiting their applications. Additionally, the printing station teaches a chamber either integrated with or enclosing the 3D printer to provide temperature, pressure, and humidity control during the printing process.

Abstract: An apparatus and method for multi-stage printing teaches means for removing and replacing a printed component during the printing process and accurately placing the component in the printer for continuation of the printing process. This can be accomplished through the use of a scanner, probe machine, or scanning Additionally, the present invention teaches the use of heating means in combination with a 3D printer to overcome additional issues with multi-sage printing.