Abstract: Computing resource service providers may provide computing resources to customers in a multi-tenant environment. These computing resources may be behind a firewall or other security device such that certain information does not reach the computing resources provided to the customer. A logging entity may be implemented on computer server operated by the computing resource service provider. The logging entity may obtain log information from the firewall or other security device and store the log information such that it is accessible to the customer. Additionally, the log information may be provided to other services such as a metrics service or intrusion detection service.

Abstract: A method is disclosed for manufacturing a joint. The method may include depositing a first plurality of paths within a first layer. Each of the first plurality of paths may have a center portion, a first portion extending away from the center portion to at least partially form a first branch, and a second portion integral extending away from the center portion opposite the first portion to at least partially form a second branch. The method may further include depositing a second plurality of paths primarily within the first layer. Each of the second plurality of paths may have a center portion, and a first portion extending away from the center portion to at least partially form a third branch of the joint. The second plurality of paths may cross over and be bonded to the first plurality of paths to form spaced-apart bumps that extend into a second layer.

Abstract: A system is disclosed for additively manufacturing a composite structure. The system may include a support, and a print head operatively connected to and moveable by the support. The print head may include a first supply configured to hold a liquid matrix, a second supply configured to hold a continuous reinforcement, and a wetting module configured to separately receive the liquid matrix and the continuous reinforcement from the first and second supplies, respectively, and to discharge a composite material including the continuous reinforcement wetted with the liquid matrix. The wetting module may include a body forming an internal chamber having an upstream open end and a downstream open end, an entrant nozzle disposed within the upstream open end and configured to receive the continuous reinforcement, and an exit nozzle disposed within the downstream closed end and configured to discharge the composite material.

Abstract: A method is disclosed for manufacturing a joint. The method may include depositing a first path of composite material within a first layer at the joint. The first path may have a center at a center of the joint, a first portion integral with the center portion and extending away from the center portion, and a second portion integral with the center and extending away from the center portion. The method may further include depositing a second path of composite material within the first layer at the joint. The second path may have a center at the center of the joint, and a first portion integral with the center of the second path and extending away from the center of the second path. The center portion of the second path may be parallel with, abut and be bonded to the center portion of the first path.

Abstract: A method is disclosed for manufacturing a joint. The method may include depositing a first plurality of paths within a first layer of the structure that passes through the joint in a first configuration. The method may further include applying a transformation to the first configuration to form a second configuration. The method may additionally include depositing a second plurality of paths within a second layer of the structure to at least partially overlap the first plurality of paths and pass through the joint in the second configuration.

Abstract: A method is disclosed for additively manufacturing of a joint within a structure using a composite material. The method may include depositing a first path of the composite material within a first layer at the joint. The first path may have a center portion at a center of the joint, and a first portion integral with the center portion and extending away from the center portion. The first portion may form at least part of a first branch having a first density. The center of the joint may have a second density. The first density may be greater than the second density.

Abstract: A method is disclosed for manufacturing a joint. The method may include depositing a first plurality of paths to form a base layer of a joint in the structure. The method may also include depositing a second plurality of paths that pass through the joint. At least one of the second plurality of paths may extend away from the base layer through free space.

Abstract: A sorting system for inspected parts includes a storage assembly, a conveyance system, and a controller. The storage assembly has a plurality of bins configured to receive and store the inspected parts. The conveyance system is configured to deliver the inspected parts to the storage assembly. The controller programmed to, assign part types to each of the plurality of bins. The controller is further programmed to operate the conveyance system to deliver each of the inspected parts to one of the plurality of bins having a matching part type. The controller is further programmed to, in response to a full condition of the storage assembly, empty the inspected parts from a first the plurality of bins.

Abstract: Described herein are improved configurations for a wireless power transfer. The parameters of components of the wireless energy transfer system are adjusted to control the power delivered to the load at the device. The power output of the source amplifier is controlled to maintain a substantially 50% duty cycle at the rectifier of the device.

Abstract: An additive manufacturing system is disclosed for use in discharging a continuous reinforcement. The additive manufacturing system may include a support, and a compactor operatively connected to and movable by the support. The compactor may be configured to apply a pressure to the continuous reinforcement during discharge. The additive manufacturing system may also include a feed roller biased toward the compactor to sandwich the continuous reinforcement between the roller and the compactor, and a cutting mechanism at least partially recessed within at least one of the feed roller and the compactor. The cutting mechanism may be configured to selectively move radially outward to engage the continuous reinforcement.

Abstract: A system is disclosed for additively manufacturing a composite structure. The system may include a support, and a print head operatively connected to and moveable by the support. The print head may include an outlet configured to discharge a material in a trajectory along a central axis of the outlet, and a compactor disposed downstream of the outlet relative to the trajectory and configured to press the material transversely against an adjacent surface. The outlet may be configured to translate relative to the compacting module.

Abstract: A method for solving an optimization problem inputted by a user may include: (a) using an interface of a digital computer to receive an indication of (i) said optimization problem, (ii) one or more optimization problem specifications of a plurality of optimization problem specifications, (iii) at least one generation method and at least one evaluation method, (iv) one or more algorithms of a plurality of algorithms, wherein said one or more algorithms is configured to solve said optimization problem subject to at least said one or more optimization problem specifications using said at least one generation method and said at least one evaluation method, and (v) one or more computational platforms of a plurality of computational platforms, wherein said one or more computational platforms is configured to execute said one or more algorithms; (b) using said one or more computational platforms to execute said one or more algorithms to yield a solution to said optimization problem; and (c) providing said solution t

Abstract: A method is disclosed for additively manufacturing a structure. The method may include discharging from a print head a first layer of material inward of an outer boundary of the structure. The method may also include discharging from the print head a second layer of material adjacent the first layer and cantilevering past an edge of the first layer. The method may further include compacting a portion of the second layer of material cantilevered past the edge of the first layer to extend into and form a portion of the first layer of material.

Abstract: A system is disclosed for additively manufacturing an object. The system may include a support, and a print head operatively connected to and moveable by the support. The print head may include an outlet configured to discharge a material, a leading device, and a trailing device pivotally connected to the leading device. The leading device may be configured to engage and move over the material after discharge. The trailing device may be configured to engage and move over the material at a location trailing the leading device.

Abstract: A system is disclosed for additively manufacturing an object. The system may include a first module configured to discharge a composite material including a continuous reinforcement and a matrix, and a cutting module located downstream of the first module and configured to sever the continuous reinforcement discharging from the first module. The cutting module may include a cutting mechanism configured to engage the continuous reinforcement, and a guide moveable to selectively abut the reinforcement during engagement of the reinforcement by the cutting mechanism.

Abstract: An intraluminal imaging device includes a flexible elongate member configured to be positioned within a body lumen of a patient. An ultrasound imaging assembly is disposed at the distal portion of the flexible elongate member. In some embodiments, a tip member with a protrusion is coupled to the ultrasound imaging assembly. The ultrasound imaging assembly and/or the flexible elongate member includes a recess that that receives the protrusion. In some embodiments, a support member includes a first stand, a second stand, a third stand, and a ridge. A flexible substrate with integrated circuit chips and an ultrasound transducer assembly is positioned around the support member. A filling material and an acoustic backing material are disposed in different spaces defined by the stands and flexible substrate. A tip member includes a groove receiving the ridge.

Abstract: A system is disclosed for additively manufacturing an object. The system may include a support, and a print head operatively connected to and moveable by the support. The print head may include a supply module configured to hold a reinforcement, and a wetting module. The wetting module may include a body with an inlet configured to separately receive the reinforcement and a matrix, and an outlet configured to discharge the reinforcement wetted with the matrix. The print head may also include a teasing mechanism disposed between the inlet and the outlet. The teasing mechanism may have multiple operating positions configured to affect varying levels of pressure against the reinforcement.

Abstract: A nozzle is disclosed for use in an additive manufacturing print head. The nozzle may include a body having a central passage with an entrant end and an exit end, and a shoulder protruding radially outward from the body at a location between the entrant and exit ends. A groove may be formed within an outer surface of the body at a location between the shoulder and the entrant end. The groove may be configured to receive a seal.

Abstract: A photonic bolometer includes: a photonic chip; a weak thermal link; a thermally-isolated member, and the weak thermal link thermally isolates the thermally-isolated member from the photonic chip; a photonic temperature sensor; a chip waveguide in optical communication with the photonic temperature sensor; and a photon absorber that receives incident radiation light, increases temperature due to absorption of the incident radiation light, heats the photonic temperature sensor in response to receipt of the incident radiation light, and changes the resonance frequency of the photonic temperature sensor in response to receiving the incident radiation light.